Mitsubishi Electronics T 60 User Manual

T-60 Operator’s Manual  
P/N 400248-00  
Rev.: A3  
Date: November1, 1995  
T-60 Operator’s Manual  
Information furnished by EMERSON EMC is believed to be accurate and  
reliable. However, no responsibility is assumed by EMERSON EMC for its  
use. EMERSON EMC reserves the right to change the design or operation of  
the equipment described herein and any associated motion products without  
notice. EMERSON EMC also assumes no responsibility for any errors that  
may appear in this document. Information in document is subject to change  
without notice.  
P/N 400248-00  
Rev.: A3  
Date: November 1, 1995  
i
ii  
Customer Services  
EMERSON EMC offers a wide range of services to support our customer’s  
needs. Listed below are some examples of these services.  
Service Support (612) 474-8833  
Emerson Electronic Motion Control’s products are backed by a team of  
professionals who will service your installation wherever it may be. Our  
customer service center in Minneapolis, Minnesota is ready to help you solve  
those occasional problems over the telephone. Our customer service center is  
available 24 hours a day for emergency service to help speed any problem  
solving. Also, all hardware replacement parts, should they ever be needed,  
are available through our customer service organization. Need on-site help?  
EMERSON EMC provides on-site service, in most cases, the next day. Just  
call EMERSON EMC’s customer service center when on-site service or  
maintenance is required.  
Training Services (612) 474-1116  
EMERSON EMC maintains a highly trained staff of instructors to  
familiarize customers with EMERSON EMC’s products and their  
applications. A number of courses are offered, many of which can be taught in  
your plant upon request.  
Application Engineering (612) 474-1116  
An experienced staff of factory application engineers provide complete  
customer support for tough or complex applications. Our engineers offer you  
a broad base of experience and knowledge of electronic motion control  
applications.  
Bulletin Board System (612) 474-8835  
EMERSON EMC maintains a BBS which provides you access to software  
updates, and technical information and services.  
Communications protocol:  
300-14,400 baud, N, 8, 1  
FAX (612) 474-8711  
iii  
Table of Contents  
Table of Contents  
Customer Services............................................................................ii  
Introduction....................................................................................... 1  
Features............................................................................................. 1  
T-60 Overview.................................................................................. 2  
Functional Description ..................................................................... 2  
Installation......................................................................................... 5  
Unpacking and Inspection................................................................ 5  
Through Panel Mounting ................................................................. 6  
System Interconnect ......................................................................... 8  
Power / RS422 Connector.............................................................. 8  
IBM PC-XT Keyboard Connector.................................................. 8  
COM1 and COM2 Connectors ...................................................... 9  
RS422 and RS485 Communications............................................. 9  
I/O Connector............................................................................... 11  
ApplicationBuilder......................................................................... 13  
Getting Started ............................................................................... 13  
Simple Example........................................................................... 15  
Trouble-Shooting Communications ............................................... 16  
Operating Modes............................................................................. 17  
Builder Mode................................................................................... 18  
Operating the Builder ................................................................. 18  
Editor Mode..................................................................................... 20  
Terminal Mode................................................................................ 21  
File Menu ........................................................................................ 21  
Transfer Menu ................................................................................ 22  
Setting Menu................................................................................... 22  
Summary of ApplicationBuilder Operation................................... 24  
Screen Editor .................................................................................. 27  
Editor Capabilities.......................................................................... 27  
Help Key....................................................................................... 28  
Application Examples ................................................................... 31  
Communicating with the Operator................................................ 31  
Serial Communications made Simple ........................................... 31  
Parallel I/O Made Simple............................................................... 32  
EMERSON EMC DX Drive Demo Program............................... 32  
Installation................................................................................... 32  
Using The T-60 With One or More DX Drives .............................. 34  
T-60 Basic Programming Language ........................................... 37  
Variables, Constants, and Strings ................................................. 37  
Array Variables............................................................................... 38  
Arithmetic Operation...................................................................... 38  
Relational Operations..................................................................... 39  
Logical Operators............................................................................ 39  
Functional Operators...................................................................... 40  
String Operators ............................................................................. 40  
EMERSON Basic Statements, Commands, and Functions ......... 42  
64K Memory Option ....................................................................... 45  
Adding Memory Options to the T-60 ............................................. 45  
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T-60 Operator's Manual  
Changing ROMS in the T-60.......................................................... 46  
Changing the Battery in a T-60 ................................................... 49  
Real Time Clock ............................................................................. 51  
Adding the Real -Time Clock to the T-60 ...................................... 51  
Event Driven Software.................................................................. 53  
Hardware Reference ..................................................................... 55  
Electrical /Mechanical Specifications ............................................ 55  
Connector Pin-Out Specifications.............................................. 57  
PLC Interface Commands............................................................. 59  
Introduction..................................................................................... 59  
CALL PLCINIT Statement ........................................................... 61  
CALL PLCREAD Statement.......................................................... 63  
CALL PLCWRITE Statement........................................................ 65  
PLC Specific Information ............................................................... 66  
-MOD Interface Option ............................................................ 69  
-GE9 Interface Option.............................................................. 71  
-TI3 Interface Option ............................................................... 73  
-TI5 Interface Option ............................................................... 75  
-PL5 Interface Option............................................................... 77  
-SL5 Interface Option............................................................... 83  
CALL PLCREAD Statement ................................................... 85  
-OM1 Interface Option ............................................................. 89  
-PL2 Interface Option (Preliminary)....................................... 93  
-IDEC FA-1J\FA2-J Interface Option .................................... 95  
-Mitsubishi FX PLC Interface ( -MFX ) .................................. 99  
-SQD SQUARE D SY/MAX PLC Interface ........................... 105  
Appendix - A List of Figures ...................................................... A-1  
Appendix - B List of Tables ........................................................ B-1  
vi  
Table of Contents  
vii  
Introduction  
Features  
Introduction  
Features  
8 line by 40 character backlit LCD display with graphics.  
Powerful I/O capability.  
2 serial ports (1 port can be RS232, RS422, OR RS485).  
8 parallel I/O lines.  
IBM keyboard interface.  
All I/O is optically isolated.  
Fully featured BASIC programming language.  
Interrupt capability.  
Floating point math.  
Formatted data entry graphics.  
Easy to use commands for on-board I/O.  
Programmable, context sensitive help key.  
NEMA4 panel mount or wall mount housing.  
Powerful PC-based ApplicationBuilder software included.  
Automatically builds BASIC programs.  
Place text on the T-60’s screen in a wordprocessor like manner.  
Build comples programs without in-depth knowledge of BASIC.  
Exchange programs between the PC and the T-60.  
Built-in terminal emulator.  
Large full-travel 30 key waterproof keypad.  
9 soft keys.  
Tactile feedback.  
1
T-60 Operator's Manual  
T-60 Overview  
The T-60 Operator Interface Terminal allows you to set up and operate  
EMERSON EMC positioning servo drive products. The T-60 provides overall  
control and operator interface for any type of controller or computer which  
needs an easy to use, intelligent operator interface.  
With a T-60 an operator can view and change machine parameters or follow  
instructions to perform operations. Operators do not have to set switches,  
thumbwheels or indicator lights. A back-lit 8 line by 40 character  
“super-twist” LCD display and a large full-travel 30 key waterproof keypad  
prompts and “listens” to the operator through machine operations. By  
programmming the Help functionkey, operators have as little or as much  
“HELP” information as required. The T-60’s LCD screen displays TEXT or  
GRAPHICS providing the operator with block diagrams, flow charts, wiring  
diagrams and statistical information.  
For machine control, the T-60 provides 8 lines of parallel I/O, two serial ports  
(one is software configurable to be either RS-232 RS-422, or RS-485), and 8  
timers to facilitate machine monitoring and control functions. All I/O’s are  
optically isolated and designed to be extremely noise tolerant.  
Included with the T-60 is a disk containing the ApplicationBuilder; a PC DOS  
program which allows you to quickly generate programs for the T-60. The  
ApplicationBuilder generates BASIC programs from simple menu selections  
and direct screen entry of text. It consists of three components:  
BUILDER - converts menu selections and direct screen text entry into  
BASIC code  
EDITOR - performs text editing of BASIC or other ASCII files  
TERMINAL EMULATOR - performs “dumb” terminal operation to talk  
to the T-60.  
Integrated into all ApplicationBuilder functions is an UPLOAD/DOWNLOAD  
capability and a comprehensive, context sensitive HELP system.  
Functional Description  
The T-60 is housed in a rugged cast housing which can be flush mounted to an  
equipment panel. A full gasket and a rigid mounting system forms a water tight  
seal about the opening. The display is sealed and the keypad is constructed of a  
water tight silicone rubber. If being water tight is not critical to your application,  
the T-60 can be wall mounted with supplied brackets.  
The keypad on the front of the T-60 is organized into three color coded  
groups:  
WHITENumeric Entry  
BLUE Action - CURSOR, ENTER, INSERT, DELETE, HELP  
YELLOW Function Keys  
2
Introduction  
Functional Description  
The 8 line by 40 character LCD display serves as a display port,  
programming tool and soft key label. In the edit mode, the display can be  
used to scroll through text, make changes, or debug programs. In the run  
mode text, soft key titles and graphics can be displayed under program  
control.  
The bottom of the T-60 incorporates the entire connector system for parallel  
and serial I/O.  
Figure 1  
Block Diagram  
Figure 1 diagrams the internal components of the T-60. The heart of the unit  
is a high speed 64180, 8 bit high integration CPU chip. The CPU  
communicates with UARTS (serial ports), ROM, RAM, TIMERS, and I/O.  
Battery backed-up RAM stores programs and variables even if the power is  
removed. It can hold a program for over 5 years without power applied. The  
opto-isolation circuitry is designed to provide a barrier between the outside  
world (I/O ports) and the CPU. This eliminates CPU errors in high noise  
environments. The serial and parallel ports have their own power supply to  
further insure that noise does not disrupt the CPU’s operation.  
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T-60 Operator's Manual  
4
Installation  
Unpacking and Inspection  
Installation  
This chapter focuses on the steps necessary to unpack and install the T-60.  
Read this section before attempting to apply the T-60. System installers  
should read this chapter before attempting to install the unit into a cabinet,  
or before connecting any electrical power to the T-60.  
Unpacking and Inspection  
Inspect the T-60’s shipping container. Is there evidence of damage or  
mishandling? If damage exists contact your shipping carrier immediately.  
EMERSON EMC cannot be held responsible for damage in shipment.  
Compare the contents of the container with the packing list which is attached  
to the exterior of the shipping container. Your T-60 shipping container  
should include the following:  
T-60 with installed options  
This manual  
EMERSON BASIC PROGRAMMING GUIDE  
ApplicationBuilder diskettes  
Mounting clips (four)  
Mounting brackets (two)  
1/4" 8-32 Screws (four)  
Mounting template  
Optional cables and connectors as indicated on the packing list.  
If any items are missing or  
damaged, contact EMERSON  
EMC immediately.  
A null modem cable  
NMA 9 pin to 9 pin  
NMX 25 pin to 25 pin  
TIA-XXX T-60 to DX Amplifier cable  
5
T-60 Operator's Manual  
Through Panel Mounting  
The T-60 is designed to be mounted either through an equipment panel (in a  
panel cut-out) or on a flat surface. The through-panel mounting will allow  
the T-60 to meet NEMA4 specifications for water resistance, and will also  
resist dust, dirt and non corrosive chemicals. Improper installation could  
result in damage to the T-60 and other equipment installed in or adjacent to  
the panel containing the T-60. For safety reasons please follow these  
instructions closely.  
1. Prepare the opening in the panel.  
a. Tape the enclosed mounting template to the front of the panel in  
the desired location (see Figure 2).  
b. Drill 3/8 “ inside the cutout to facilitate cutting.  
c. Use a sabre saw or some other type of sheet metal cutting device  
to cut out along the ”cut here" line.  
d. Using a file, carefully remove any burrs or rough edges that may  
cut or scratch during the remainder of the installation.  
e. Remove the paper template and discard.  
2. Carefully insert the T-60 into the hole in the panel from the front side (see  
Figure 3).  
Figure 2  
Panel Cut-Out  
3. Hold the T-60 to the panel, and insert the mounting clips as shown in  
Figure 4.  
a. If the T-60 is to be used in continuously wet applications, we recommend  
that the installer apply a silicone sealer to the gasket prior to installation.  
4. Tighten the mounting clips to secure the T-60 to the front panel.  
5. Inspect that the T-60 fits snugly up against the front panel, and that there  
are no gaps or holes that may allow water or dirt to enter the cabinet.  
6
Installation  
Through Panel Mounting  
Figure 3  
Mounting  
Figure 4  
Mounting Clips  
7
T-60 Operator's Manual  
System Interconnect  
The T-60 is designed to meet a variety of applications; therefore, it is  
impossible to describe a “standard” interconnect for the T-60. This section  
will describe each individual connector on the T-60 and how to apply them.  
Figure 5  
T-60 Bottom Panel  
Power / RS422 Connector  
The Power/RS422 Connector is an 8 pin screw terminal type connector which  
provides the DC input power and the RS422 / RS485 connections. The T-60 can  
accept from 9V to 30V DC at 6 watts. The T-60 actually tries to begin working as  
soon as the power source passes 4.5 V. This means that at start-up the current  
requirements from the DC power source can exceed 1.3 Amps. This current surge  
may cause some power sources to enter current limit rather than to begin working.  
For this reason it is recommended that the T-60 be used with a power source  
which is uneffected by this type of current surge. Unregulated supplies, linear  
power supplies, or high current (2 Amp) switching supplies are recommended.Only  
connect the DC power source to the DC IN + and the DC IN -. These inputs are  
reverse protected. DO NOT connect the DC power ground to LOGIC GROUND.  
Logic Ground, as with all I/O is optically isolated from the I/O. Connecting Logic  
Ground to DC IN - will result in lower noise immunity.  
For connections to the RS422 connector, refer to section “RS422 and RS485  
Connections”.  
IBM PC-XT Keyboard Connector  
An industry standard IBM PC XT keyboard can be connected into the 5 pin  
DIN connector on the bottom panel of the T-60. Some keyboards have  
switches which select XT or AT mode. Be sure that the switch is in the XT  
mode. Some “auto-switch” type keyboards may not work with the T-60. If  
the keyboard you select is an universal keyboard, make sure it has a switch.  
Note that the IBM KEYBOARD connector is not optically isolated, and use in  
a high noise environment should be avoided. The primary use for this  
connector and the IBM keyboard is for program development. If necessary,  
remove the keyboard from the connector while running your application.  
8
Installation  
System Interconnect  
COM1 and COM2 Connectors  
COM1 and COM2 are the serial port connectors (DB-9 style, male). The  
pin-outs for these connectors are as follows:  
Table 1  
COM1 and COM2 Connectors  
Pin-Outs  
Pin:  
Connection:  
SHIELD  
Housing  
2
3
5
RS232 RECIEVE (INPUT)  
RS232TRANSMIT (OUTPUT)  
SIGNAL GROUND  
These connectors provide connection for serial communications between the  
T-60 and a variety of devices. Connections made with this connector are  
most commonly referred to as SERIAL PORTS. Examine your application  
carefully, and make sure that you have TRANSMIT on the T-60 connected to  
the RECEIVE of the device under control, and RECEIVE of the T-60  
connected to the TRANSMIT of the device under control.  
Figure 6  
RS232 Minimum Connections  
RS422 and RS485 Communications  
The T-60 can communicate via RS422 or RS485 on COM1. When either of  
these modes are selected, the RS232 COM1 connector is disabled. To use the  
RS422 connections, follow the same conventions outlined for RS232,  
connecting outputs on the T-60 to inputs on the device under control, and  
inputs on the T-60 to outputs on the device under control. To enable the  
RS422 transmitter, refer to the RS422 Statement in the EMERSON EMC  
Basic Programming Guide. Figure 7 depicts proper RS422 connections.  
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T-60 Operator's Manual  
Figure 7  
RS422 Connections  
To perform RS485 serial communications with the T-60, the RS422  
transmitter and receiver lines must be tied together. Since the RS422  
transmitters are disabled after power up, it is safe to assume that no line  
driver conflicts will occur. Again, refer to the RS422 Statement in the  
EMERSON EMC BASIC PROGRAMMING GUIDE. The electrical  
connection between the T-60 and the device under control are shown in  
Figure 8.  
Figure 8  
RS485 Connector  
10  
Installation  
System Interconnect  
I/O Connector  
The I/O connector on the T-60 is designed to provide 8 bits of parallel I/O.  
Each line can be configured in software to perform input, output, or  
bidirectional operations. The pin-out is an industry standard 20 pin ribbon  
cable, compatible with industry standard PB-8 boards. Pinout as follows  
(even numbered pins - logic ground):  
Table 2  
I/O Connector Pin-Out  
Pin:  
19  
17  
15  
13  
11  
9
Function:  
+5V DC OUT*  
I/O 0  
I/O 1  
I/O 2  
I/O 3  
I/O 4  
8
I/O 5  
5
I/O 6  
3
I/O 7  
The schematic in Figure 9 represents one I/O bit on the 8-bit I/O interface.  
All of the other 7 bits are identical. U1 is a CMOS receiver which is  
constantly monitoring the status of the I/O line. Its input is current limited  
by R2 and pulled up by R1. A current limit (R2) is needed to allow the I/O  
pin to exceed the supply voltage of U1 without damage. Notice that the  
pull-up (R1) is a fairly high value (22K ohms). This allows the user to  
connect any voltage from 5 to 30VDC to the pin without damage to the  
pull-up resistor. U1 senses a logic high (1) on the I/O pin at 3.2 V and a logic  
low (0) on the I/O pin at 1.4 V regardless of the externally applied pull-up  
voltage.  
U2 is an open collector output driver which can withstand 30 V and 30 MA  
load. When a BASIC program writes a 1 to the output port, U2 is off,  
allowing the pull-up resistor (R1) or the user’s externally connected pull-up to  
pull the I/O line high. It is possible in this condition for an external device  
like a switch to pull the line low thereby allowing the input U1 to sense a  
logic low. When a BASIC program writes a 1 to the output port, the output  
transistor in U2 turns on, thereby driving the I/O line low. When the T-60  
powers up, all I/O lines are driven to a 1, thereby allowing the I/O pins to  
operate as inputs.Use the OUT and INP commands to program the T-60’s 8  
bit I/O port. They are described in detail in the EMERSON EMC BASIC  
PROGRAMMING GUIDE.  
11  
T-60 Operator's Manual  
Figure 9  
One Channel of the 8 Bit I/O  
Support for the T-60’s 8 bit I/O has been provided by the following  
commands. Some commands refer to 24 bits of I/O instead of 8. This reflects  
the compatability between the T-60 and the T-61 (the T-61 has 24 bits of I/O  
standard while the T-60 has 8 bits of I/O). The T-60 can only use the lower 8  
bits of these commands.  
INP  
IO24  
ON IO24  
OUT  
Input port data  
Specify an I/O bit pattern to generate an interrupt.  
Interrupt on an I/O bit pattern  
Output port data  
These commands are described in the EMERSON EMC BASIC USERS  
GUIDE in a manner which works with both the EMERSON EMC T-61 and  
T-60. The specific changes are as follows:  
INP  
IO24  
Input range of 0 to 255.  
Bit pattern ranges: “0”, “1” or “X” through “00000000”,  
“11111111”, or “XXXXXXXX”. the input may still be a  
string variable.  
ON IO24  
OUT  
Unchanged.  
Output range 2 to 255. The MAP function works over  
the range of: “0”, “1” or “X” through “00000000”,  
“11111111”, or “XXXXXXXX”.  
There are similar restrictions on the use of the EVENT DRIVEN SOFTWARE.  
I/O ranges are limited to 8 bits. If you have questions about the EVENT DRIVEN  
SOFTWARE and the T-60, please contact EMERSON EMC.  
12  
ApplicationBuilder  
Getting Started  
ApplicationBuilder  
Included with your T-60 is a disk containing the ApplicationBuilder, a PC  
program which allows you to quickly generate programs for the T-60. The  
ApplicationBuilder generates BASIC programs from simple menu selections  
and direct screen entry of text. It consists of three components: the  
BUILDER, which converts menu selections and direct screen text entry into  
BASIC code; the EDITOR which performs text editing of BASIC or other  
ASCII files; and a TERMINAL EMULATOR which can perform “dumb”  
terminal operation to talk to the T-60. Integrated into all ApplicationBuilder  
functions is an UPLOAD/DOWNLOAD capability and a comprehensive,  
context sensitive HELP system.  
Getting Started  
Running the ApplicationBuilder is quite simple, and requires no special  
software skills. First you must connect the T-60 to your PC. Connect one  
end of the NULL MODEM cable to COM2 on the T-60 and the other end to  
an available serial port on your PC (either COM1 or COM2). Note which  
serial port on the PC that you have connected to (for information on the serial  
ports for your PC refer to your PC’s instruction manual).  
Figure 10  
Serial Connections  
The ApplicationBuilder is supplied on two 5 1/4" diskettes and on one 3 1/2"  
diskette. Make back-up copies of your diskettes before attempting to use  
them. Save your original ApplicationBuilder diskettes in a safe place.  
13  
T-60 Operator's Manual  
If your system has a hard drive, copy the contents of either of the diskettes  
onto the hard drive (make a separate directory first for ease of use). If you do  
not have a hard drive, place the disk labeled DISK 1 into your diskette  
drive.Log onto the drive with the ApplicationBuilder on it (i.e.. type A: or B:  
or C: followed by Enter). Type BUILD followed by Enter to run the  
ApplicationBuilder. If you wait a few minutes and your screen remains  
blank, remove the disk and reboot your computer. Re-run the  
ApplicationBuilder by logging onto the dirve containing the  
ApplicationBuilder and typing BUILD X followed by Enter.  
The ApplicationBuilder will start up for the first time in LCD mode (the simplest  
display mode). If your computer has a color monitor, selecting the SETTINGS  
menu by pressing ALT-S, and choose the COLOR selection by moving the cursor to  
the COLOR text followed by ENTER. This will display ApplicationBuilder screens  
in color. The change you have just made will be recorded to a configuration file on  
disk, so subsequent operation of the program will be in color.  
To select the COM port on your PC which is connected to the T-60, press ALT-S to  
pull down the SETTINGS menu. Choose either COM 1 or COM 2 depending upon  
which port the null modem cable is connected to on your PC. Perform the selection  
in the same manner described above. Again, the settings will automatically be  
saved for you when you exit the ApplicationBuilder program.  
Figure 15 shows the layout of the BUILD screen. It is comprised of four basic  
components. At the top there is the MENU BAR. This is where the pull-down  
menus for operating the ApplicationBuilder originate. In the center is the  
PSEUDOCODE GENERATION area. This is where English language program  
statements which we call PSEUDOCODE are placed and edited. In the lower left  
is the SIMULATION of the T-60’s screen. This represents the 8 line by 40  
character LCD screen on the T-60. The lower right contains descriptions for the  
function keys. These keys are used to generate the PSEUDOCODE.  
Figure 11  
Builder Mode Screen  
14  
ApplicationBuilder  
Getting Started  
Simple Example  
To demonstrate the power of the ApplicationBuilder, a very simple example  
program will be read from disk, viewed, converted to BASIC, downloaded,  
and run.  
Select the FILE menu (ALT-F) and OPEN (move the cursor or type O)  
followed by ENTER. You will see a window appear which contains a listing  
of the demonstration builder files on the ApplicationBuilder diskette. Move  
the highlight to EASY.BLD and press ENTER. The PSEUDOCODE for  
EASY.BLD will appear on the screen. Scroll up and down through the  
PSEUDOCODE with the cursor keys. Here is a listing of the PSEUDOCODE  
for EASY.BLD:  
- GOTO SCREEN begin  
*>SCREEN begin  
- PUT TEXT AT (7,7): “PRESS THE ‘MORE’ SOFTKEY”  
- PUT LARGE TEXT AT (3,3): “TO THE BUILDER”  
- PUT HUGE TEXT AT (2,1): “WELCOME”  
- SOFTKEY (1) “MORE” GOTO SCREEN morescr  
- SOFTKEY WAIT  
*>SCREEN morescr  
- PUT LARGE TEXT AT (3,1): “EMERSON EMC”  
- PUT LARGE TEXT AT (2,2): “MAKES PROGRAMMING”  
- PUT HUGE TEXT AT (3,2): “EASY!!”  
- DELAY 2000  
- GOTO SCREEN begin  
- END OF PSEUDOCODE  
Observe the first two lines and the last line of the PSEUDOCODE. These  
three lines are automatically inserted by the BUILDER. You may have  
noticed them on the screen before you retrieved EASY.BLD from disk. These  
lines cannot be deleted, edited or moved. They are essential for the builder’s  
operation. Notice that each line begins with a dash (-) or a * sequence. These  
tell the BUILDER that the line is PSEUDOCODE, and what to do with it.  
A line starting with * is a new screen, while a line starting with a dash is  
PSEUDOCODE that will execute for that screen. Don’t worry about  
generating these special symbols, the BUILDER does that for you.  
Next move the cursor (blinking block) over the “*SCREEN begin”  
PSEUDOCODE. Notice that the SIMULATION OF THE T-60’S SCREEN  
contains text. This is the text which will be placed on the T-60 actual screen  
when BASIC is generated and the program is run on the T-60. Now try  
placing the cursor over the fourth line:  
- PUT TEXT AT (7,7): “PRESS THE ‘MORE’ SOFTKEY”  
Press ENTER. Notice that the “PRESS THE ‘MORE’ SOFTKEY” is  
highlighted on the T-60’s screen. If you hold down the SHIFT key and move  
the cursor key, the text block will move on the screen. Notice that the two  
numbers in parentheses are changing. This action changes the place where  
the BUILDER will place the BASIC text string when the PSEUDOCODE is  
converted to BASIC.Press ESC (leave the program unchanged). If you were  
to press ENTER, new position would have been saved.  
15  
T-60 Operator's Manual  
Press SOFTKEY F5. This is how you select PSEUDOCODES to place on  
screen. Type an S. Press ENTER. The SCREEN PSEUDOCODE has been  
selected. This allows you to type text directly on the screen. Press ESC  
(leave the program unchanged).  
Press SOFTKEY F8. This softkey generates BASIC. You may be asked if  
you wish to write over the existing BASIC program: answer “Y” for YES or  
press ENTER (if the ApplicationBuilder has been used before, the file  
EASY.BAS may already exist on the disk). Notice that the number of basic  
lines generated are displayed on screen during this process. You will be  
asked if you want to load the BASIC program into the EDITOR, answer YES.  
You will be asked if you want to save EASY.BLD, answer NO since you did  
not change anything (or mean to change anything!).  
The BASIC program generated by EASY.BLD is now loaded into the  
EDITOR. The EDITOR has the normal attributes of a text editor. CUT /  
PASTE / INSERT / etc. To select a block of text to cut or copy, move the  
cursor to the start of the text block and hold down the shift key and move the  
cursor to the end of the block. The selected block will be highlighted. You  
may now CUT copy COPY the text in the selected block by using the  
functions in the EDIT menu. Try pressing F1 to further examine the  
capabilities of the EDITOR. After examining the BASIC code generated, let’s  
download it into the T-60.  
Press ALT-T and select Download Disk File (by selecting it and pressing  
Enter or by typing “D”). Select EASY.BAS and press ENTER. This begins  
the download process from the PC to the T-60. While data is transferred  
between the PC and the T-60, a counter will show the number of bytes being  
transferred. When the process is complete, the program has been  
downloaded. Press F1 (RUN) on the T-60. You should see the screens and  
softkeys that were present on the SIMULATION OF THE T-60’S SCREEN  
on the PC.  
Once you have successfully downloaded and run EASY.BLD, try loading,  
examining, and compiling other programs on the ApplicationBuilder  
diskette. Some programs are only available in BASIC form. They may be  
loaded with the ApplicationBuilder even though their corresponding  
BUILDER file is not present.  
Trouble-Shooting Communications  
If your attempt at down-loading a program to the T-60 was unsuccessful,  
check the serial port connections between the T-60 and the PC. Look for the  
following things:  
1. Is power applied to the T-60?  
2. Is one end of the NULL MODEM cable connected to COM 2 of the T-60?  
If it is not, reconnect it to COM 2.  
3. Which port on the PC is the other end of the serial cable connected to:  
COM 1 or COM 2? Does this match with the selections made in the  
SETTINGS menu? If you are unsure, recheck the SETTINGS menu  
(ALT-S) and make sure that you have the correct setting.  
16  
ApplicationBuilder  
Operating Modes  
4. Are the NULL MODEM cable connectors securely seated into their  
respective sockets? Try tightening the hold-down screws on the NULL  
MODEM cable.  
5. Are you using the NULL MODEM cable supplied by EMERSON EMC?  
If not, check the cable for correct configuration.  
6. Do you have memory resident programs loaded (TSR programs) which  
are presently running on your PC (disk spoolers, communications drivers,  
etc.)? If so disable or remove them. TSR’s may cause problems with the  
serial port operation.  
Operating Modes  
This portion of the manual has been created from excerpts of the on-line HELP  
which is integrated into the ApplicationBuilder program. If you feel comfortable  
with the discussion so far, go ahead and try the ApplicationBuilder on your own.  
If you need help at any time, press F1. A help message will appear which will  
describe the operation required to run the ApplicationBuilder. After trying out  
the ApplicationBuilder, read this section of the manual to master its power.  
Section “Summary of ApplicationBuilder” contains a keystroke summary.  
The ApplicationBuilder consists of three basic operating modes: BUILDER,  
EDITOR, and the TERMINAL modes. These modes are selected by the  
MODE menu. When the ApplicationBuilder begins, it starts up in the  
BUILDER mode. To change modes, use the MODE menu. The Mode menu  
gives you access to the Builder, the Editor, and the Terminal Modes of the  
ApplicationBuilder. You can switch from mode to mode without closing the  
current document allowing you to work on a number of things at once. You  
also quit the program from the Mode menu. You can access the Mode menu  
by hitting the <Esc> key or Alt-M.  
BUILDER - The Builder Mode is the mode you utilize to use a user friendly  
program generation environment to help you develop your BASIC program  
to run on your T-60. Typing “B” while anywhere in the Mode menu will also  
activate this command.  
EDITOR - The Editor Mode is basically a standard text editor where you can  
develop and modify your BASIC programs. Not only can you cut, copy, and  
paste blocks of text, but you can also renumber your BASIC programs in the  
Editor. Typing “E” while anywhere in the Mode menu will also activate this  
mode.  
TERMINAL - The Terminal Mode basically turns your computer into a  
dumb terminal that communicates directly to the T-60’s interface. For all  
practical purposes, key strokes entered onto your computer keyboard are  
echoed on the interface screen. Typing “T” while anywhere in the Mode  
menu will also activate this command.  
RUN TUTORIAL - This selection provides a guided tour of the  
ApplicationBuilder. Text will be placed on-screen with examples of how to  
run the ApplicationBuilder.  
QUIT - Exits the ApplicationBuilder program and returns you to DOS.  
Typing “Q” while anywhere in the Mode menu will also activate this  
command.  
17  
T-60 Operator's Manual  
Builder Mode  
The Builder Mode is the heart of the ApplicationBuilder package. It allows  
you to easily develop a control and interface program, test the operator  
interface functionality of the program, and then generate the proper BASIC  
code to run in a T-60. You accomplish this by generating “Pseudocode”. You  
can enter a line of Pseudocode by pressing F5, finding the appropriate  
Pseudocode for the task you want to accomplish, pressing Enter, and  
following the instructions for entering the requested data. You write a  
program in Pseudocode that represents what you want the interface and  
control program to do. Not all of the functionality of the Emerson BASIC is  
represented in Pseudocodes. At any time in the process of generating the  
program you find that you need functionality that the current Pseudocodes  
don’t provide, you can press F6 and enter BASIC directly. Once you have a  
Pseudocode (and possibly Basic) representation of what you want your  
program to do, you press F8 which converts your Pseudocode program into a  
line numbered BASIC program.  
The EDITOR functions are available while operating the BUILDER. You can  
cut and copy text blocks from one section of your Pseudocode to another.  
Refer to the EDITOR for operation examples.  
Operating the Builder  
The box in the lower left hand corner of your computer screen is a  
representation of your T-60’s screen. While you are generating your  
Pseudocode program, any line of code that generates information that will be  
displayed on the LCD display will show up here. Text, soft key labels,  
placeholders for variable and operator numeric entry will all show up and can  
be moved to any legal location you desire. You will find that as you move the  
cursor down from Pseudocode line to Pseudocode line, the screen will build up  
one line at a time in synchronization with the Pseudocode line you are on.  
There are a few other important keys and keystrokes to keep in mind. Ctrl-Y  
will delete the line of Pseudocode where the cursor is currently located. Cut,  
Copy and Paste are all functions which allow blocks of Pseudocode to be  
manipulated. Pressing F5 when the cursor is on a line of Pseudocode will  
add a new line of Pseudocode above the cursor location. Pressing Enter while  
on a line of Pseudocode will allow you to edit that line.The Pseudocode you  
generate will be organized into Screens. Each screen will have a name  
(defined by the SCREEN Pseudocode). The GOTO screen and SOFTKEY  
Pseudocodes will allow your program to move from screen to screen. F2, F3,  
and F4 help you navigate through your Pseudocode program as you are  
developing it. If you are on a line of Pseudocode that defines a GOTO or  
GOSUB to a screen or a label and press F2, the cursor will move to the  
beginning of that screen or to that label. F4 will send you to the beginning of  
the next screen definition. F3 will send you to the beginning of the previous  
screen definition. These function keys become increasingly helpful as your  
programs get longer and more involved.  
18  
ApplicationBuilder  
Builder Mode  
Entering Pseudocode falls into two categories: Entering/placing text on the  
screen and everything else. Pseudocodes that have nothing to do with text on  
screen are relatively simple. Each bit of information needed to complete a  
Pseudocode command is asked for one piece at a time. You can get from  
entry to entry with the Tab key or the Enter key. The Enter key causes you  
to exit the Pseudocode entry box once everything has been defined. The Tab  
key takes you from entry to entry and from the last entry to the first without  
exiting the screen. Shift-Tab takes you backwards.On Screen entry allows  
you to do even more powerful things. Any command that generates text to be  
placed on the screen takes advantage of On Screen Editing. The SCREEN  
command allows you to place regular text, large text and huge text at any  
location on the screen. When entering text on screen, you are always in  
overtype mode. You change text sizes with the Tab key. Once you are done  
typing the text to be displayed on the screen, you press Enter and are then  
prompted for a name for the screen. Once that is done (and you press Enter  
again) you will see that a series of PUT TEXT commands have been  
generated. Whenever you are entering a new PUT TEXT command or  
editing an existing one, your cursor will be on the screen. You can add or  
change text or move it around. To move text, you hold down the Shift key  
and then press Cursor keys to move the text to the desired location. Once  
you have the proper text on the screen in the proper location, press Enter to  
generate the Pseudocode.  
Certain Pseudocodes (like PUT NUMBER) allow you to specify numeric  
formats for printing numbers on the screen. You may specify a digit place  
holder with a # character. Use the decimal point (.) character for specifying  
the location of the decimal point. Use a plus(+) or minus (-) sign to specify  
the use of a sign. If you want scientific notation, use an E. For example:  
##.###  
+#.#  
###  
Specifies from 0.000 to 99.999  
Specifies from -9.9 to +9.9  
Specifies from 0 to 999  
PUT TEXT has the capability to place text from string variables directly on  
screen. The actual process to place the variable may seem a little confusing  
at first. To place the contents of a string variable with the PUT TEXT  
Pseudocode, press F5 followed by P. Select PUT TEXT with the cursor, press  
Enter. You are now in “ON SCREEN” text entry (i.e. your cursor is on the  
simulated T-60 screen and blinking). Move the cursor to the desired starting  
location of the text string. Type a dollar sign ($) followed by Enter. A new  
window will appear in the Pseudocode entry area which will ask for the name  
of the string variable (a string variable must end with a dollar sign ($)).  
Enter the string variable and press return.  
Selecting Pseudocode is simple. Pressing F5 displays a list of Pseudocodes  
that you can choose. The Pseudocode selection screen displays the  
Pseudocode list, the currently selected Pseudocode, and some helpful  
information about the currently selected Pseudocode. If you press Enter, you  
will go to the entry screen (if one is needed) for the currently selected  
Pseudocode. You can use the Up and Down Arrows, as well as the Page Up  
and Page Down keys, to scroll through the Pseudocodes. You can also press a  
letter key to get to the first command in the Pseudocode list that begins with  
that letter. For instance, if you are in the list and press S, you will go to the  
SCREEN command location in the Pseudocode list.  
19  
T-60 Operator's Manual  
Editor Mode  
Editor Mode is a text editor allowing you to edit files off line from any serial  
device (such as a T-60.) This allows you to write and modify programs away  
from your machine and to use more powerful editing features than BASIC  
has built in. With the Editor, you can easily Cut, Copy, and Paste blocks of  
text from one area or program to another. You can even cut or copy text in  
the Editor and paste it into the Builder and vice versa.  
To select text to cut or copy, you position the Cursor at one end of the block of  
text in question. Then hold down the Shift key as you move the cursor with  
the Arrow keys and Page up/Page down keys. You then select Cut or Copy  
from the Edit menu. You can also use Shift-Delete or Ctrl-Insert,  
respectively, to perform the same functions. You can Paste the text  
anywhere you put the cursor (or over any block of text you choose) by  
choosing Paste from the Edit menu or by using Shift-Insert.  
When you cut or copy text from a document, it is saved in the “Clipboard.”  
You can view the clipboard at any time by choosing View Clipboard from the  
Edit menu. You will notice that the last block that was cut or copied is  
highlighted and that many of the previous cut or copied blocks are still in the  
clipboard. If you would rather paste a previously cut or copied block of text,  
just highlight that block, return to your document, and paste that previously  
(and now currently) chosen text. The following sub menus appear when you  
select the EDITOR MENU:  
CUT - Text removes the currently selected text and places it in the clipboard.  
It can then be pasted into another location or file. Typing “T” while  
anywhere in the Edit menu will also activate this command.  
COPY - Text takes a copy of the currently selected text and places it in the  
clipboard. It can then be pasted into another location or file. Typing “C”  
while anywhere in the Edit menu will also activate this command.  
PASTE - Text takes the currently selected text from the clipboard and pastes  
it into the currently selected location in your document. Unless you explicitly  
select otherwise in the clipboard, the text that is pasted will be the last block  
of text cut or copied. Typing “P” while anywhere in the Edit menu will also  
activate this command.  
SHOW - Clipboard opens the clipboard so you can view its current contents.  
You can also select text other than the most recently cut or copied text to  
paste into a document just by highlighting a different section of text. Typing  
“S” while anywhere in the Edit menu will also activate this command.  
RENUMBER - Lines acts just like the BASIC “RENUM” command if you  
have a BASIC file with a .BAS file extension loaded into the Editor. This will  
be handy if you have to insert a large number of lines of code into a BASIC  
program in the Editor. Typing “R” while anywhere in the Edit menu will  
also activate this command.  
20  
ApplicationBuilder  
File Menu  
Terminal Mode  
The Up and Down cursor keys  
Terminal Mode basically turns your computer into a dumb terminal.  
are not currently functional.  
If you want to move up or  
down on the screen, you must  
do it from the cursor keys on  
your T-60. If you are editing a  
line of BASIC, use the EDIT  
command which will position  
the cursor on the line you  
want to change.  
Virtually all keys that you hit on your keyboard are sent directly over the  
serial link from your PC to T-60. Also, anything sent out of the Emerson  
device’s serial port connected to your PC will show up on the screen of your  
PC when in Terminal Mode. In effect, using the Terminal Mode to  
communicate with the T-60 is quite a bit like typing on a keyboard plugged  
into the keyboard port on your Emerson T-60 (the exception being the use of  
<Ctrl> and function keys).  
If you enter Terminal Mode and have problems communicating, verify that  
you have the correct COM port selected in the Settings Menu and that you  
have a null modem cable between that COM port and COM2 on your  
Emerson product. Once you have verified this setup, select Start  
Communications from the Terminal menu to get things going.  
File Menu  
The File menu is used to manipulate files. You begin a New file, Open a  
preexisting file, Save a file, save a file under a different name, or Print a file.  
If you need to get to DOS briefly, the DOS Shell command allows you to go to  
DOS and get back easily. You can access the File menu by hitting Alt-F. The  
following selections appear when you select the File menu:  
NEW - closes any currently open file and starts a new one. This only affects  
the currently active mode. Typing “N” while anywhere in the File menu will  
also activate this command.  
OPEN - allows you to close any currently open file and open the file of your  
choice. You will be prompted to select from a list of acceptable files or you  
can type in the path and filename directly. Typing “O” while anywhere in the  
File menu will also activate this command.  
SAVE - immediately saves the currently active file to the most recent  
filename assigned to it. Typing “S” while anywhere in the File menu will also  
activate this command.  
SAVE_AS - saves the currently active file, but it first prompts you to specify  
a new path and/or file name. Typing “A” while anywhere in the File menu  
will also activate this command.  
PRINT - prints the currently active file to the default printer. Typing “P”  
while anywhere in the File menu will also activate this command.  
DOS SHELL - Selecting DOS Shell will send you back to DOS to take care of  
some brief task. Typing “exit” will then return you to the ApplicationBuilder.  
Typing “D” while anywhere in the File menu will also activate this  
command.  
21  
T-60 Operator's Manual  
Transfer Menu  
The Transfer menu is used to transfer files back and forth between your T-60  
and your PC. You can Download from the PC to the Emerson T-60 or Upload  
from the product to your PC. You can also Verify whether a program in your  
interface matches one on your PC or not. You can also Start and verify  
communication between the two devices. You can access the Transfer menu  
by hitting Alt-T. The following selections appear when you select the  
TRANSFER MENU:  
DOWNLOAD Disk File - transfers a file from your PC to the T-60. You will  
be prompted to select a currently saved BASIC file, or you can enter in the  
filename of the program directly. Typing “D” while anywhere in the Transfer  
menu will also activate this command.  
UPLOAD Disk File - transfers a file from your T-60 to your PC. You will be  
prompted to select a filename for the uploaded file. You can save it as an  
existing filename thereby overwriting the existing file with the uploaded file,  
or you can assign a new name to the uploaded file. Typing “U” while  
anywhere in the Transfer menu will also activate this command.  
VERIFY Disk File - compares a selected file on disk in your PC with the file  
currently loaded in the T-60. This allows you to determine which versions of  
your BASIC programs exist in the PC and the Emerson T-60. This is useful  
if, for instance, you are not sure if you have made changes in your program in  
the Emerson T-60 which are not saved on disk. If you do a Verify Disk File  
with the latest version you have on disk, and they are different, you know  
that something has changed in the T-60 since you last downloaded the  
program. Typing “V” while anywhere in the Transfer menu will also activate  
this command.  
START COMMUNICATIONS - does a number of things that will be useful  
to you. First, it stops the execution of any program currently running in your  
T-60. It then enables remote communication and verifies that the  
communication link is working correctly. Any time you cannot seem to  
communicate with your Emerson T-60, verify that you have the correct COM  
port selected in the Settings Menu and that you have a null modem cable  
between that COM port and COM2 on your Emerson T-60. Once you have  
verified this setup, select Start Communications to verify the setup. Typing  
“C” while anywhere in the Transfer menu will also activate this command.  
Setting Menu  
The Settings menu is used to configure your PC. You can specify the  
configuration of your PC’s serial ports and which serial port you will be using  
to communicate with your T-60. You can also configure the  
ApplicationBuilder to use colors which match the capability of your computer  
screen. You can access the Settings menu by hitting Alt-S. The following sub  
menus appear when you select the SETTINGS MENU:  
SELECT COM1 - Highlighting COM1 and pressing 07  
selects COM1 as the active COM port in your PC for communication with  
your T-60. Typing “1” while anywhere in the Settings menu will also activate  
COM1.  
22  
ApplicationBuilder  
Setting Menu  
SELECT COM2 - Highlighting COM2 and pressing 07  
selects COM2 as the active COM port in your PC for communication with  
your T-60. Typing “2” while anywhere in the Settings menu will also activate  
COM2.  
LCD - Highlighting LCD Mode and pressing 07  
configures the ApplicationBuilder to run effectively on a computer with an  
LCD based screen (common on laptop or notebook PC’s.) The program uses  
only black and white colors for visibility. Typing “L” while anywhere in the  
Settings menu will also put the ApplicationBuilder into LCD mode.  
MONO - Highlighting Mono/Composite Mode and pressing 07  
configures the ApplicationBuilder to run effectively on a computer with a  
Monochrome monitor The program uses black, white and intense white  
colors only for visibility. Typing “M” while anywhere in the Settings menu  
will also put the ApplicationBuilder into Mono/Composite mode.  
COLOR - Highlighting Color Mode and pressing 07  
configures the ApplicationBuilder to run effectively on a computer with a  
color monitor The program uses many colors to enhance the readability of  
the screen. Typing “C” while anywhere in the Settings menu will also put the  
ApplicationBuilder into Color mode.  
CONFIG COM1 - Selecting Configure COM1 allows you to set the  
communication parameters for COM1 in your PC. The values you can set  
are: baud rate, number of data bits, number of stop bits, parity, and whether  
you want local echo on or off. Once you have selected Configure COM1..., you  
will see a dialog box for setting these parameters with help information  
located at the bottom of the screen.  
CONFIG COM2 - Selecting Configure COM2 allows you to set the  
communication parameters for COM2 in your PC. The values you can set  
are: baud rate, number of data bits, number of stop bits, parity, and whether  
you want local echo on or off. Once you have selected Configure COM2..., you  
will see a dialog box for setting these parameters with help information  
located at the bottom of the screen.  
23  
T-60 Operator's Manual  
Summary of ApplicationBuilder Operation  
The following is a summary of the sequence of operations required to make a  
functional program in the ApplicationBuilder (this example assumes you are  
starting from the DOS prompt with the ApplicationBuilder diskette or hard  
disk ready). Your T-60 should be connected to the PC with a NULL MODEM  
cable.  
Operation:  
Keystroke:  
BUILD  
ALT-F  
Description:  
At the DOS prompt, run the  
ApplicationBuilder program.  
Running the program:  
File Menu  
“NEW” - clear out workspace and  
begin a new Pseudocode program.  
Enter  
Move the cursor to the second line  
in the Pseudocode list (*SCREEN  
begin).  
CURSOR  
Enter  
The cursor is now on the screen.  
You are now building a new  
screen named “begin”. You may  
position the cursor, enter  
Making the first screen:  
characters or press the TAB key to  
change the character size.  
This terminates the data entry  
and adds pseudocodes to your  
program which will generate the  
text you have typed on screen.  
Enter  
Move the cursor below the last  
“PUT TEXT” Pseudocode in the  
list below the begin screen.  
Cursor  
F5  
S
Select the Pseudocode list.  
Move to the “S” section.  
Adding a Softkey:  
Cursor  
Move the cursor to the Softkey.  
Select a Softkey number between  
1 and 10 (key 7 through 10 do not  
place text on screen).  
Enter Softkey number  
Enter Softkey text  
Enter the 5 character label you  
wish to place above the softkey  
Enter the name of a screen that  
you want your program to jump to  
when the softkey is pressed.  
Add 2 more softkeys in the same  
manner  
Enter screen to go to  
24  
ApplicationBuilder  
Summary of ApplicationBuilder Operation  
Operation:  
Keystroke:  
Description:  
Adds the Pseudocode to your  
program.  
Enter  
Waiting for a softkey  
F5  
S
Select the Pseudocode list.  
Move to the “S” section  
Move the cursor to the SOFTKEY  
WAIT Pseudocode.  
Cursor  
Enter  
Adds the Pseudocode to your  
program  
Move the cursor to one of the  
SOFTKEY (skey)...Pseudocodes.  
Cursor  
Building more screens:  
F2  
Goto build a screen.  
Enter  
Answer “YES” to add a new screen.  
Repeat the steps above (excluding  
the cursor positioning over the  
GOTO SCREEN BUILD), this will  
add the rest of the screens  
Repeat steps above  
necessary to build a program.  
When done adding screens:  
When done adding screens:  
Operation:  
Keystroke:  
ALT-F  
Description:  
File name  
Cursor  
Select SAVE AS.  
You will be prompted for a “SAVE  
AS” file name.  
Enter  
TAB  
Save program:  
Enter the text entry area above  
the file list.  
Enter a valid DOS filename with a  
“BLD” extension (i.e.  
Filename  
NEWFILE.BLD).  
Enter  
F8  
Save the file.  
Build BASIC  
Answer “YES” to enter the file  
into the EDITOR.  
Enter  
Convert to BASIC:  
ALT-T  
Enter  
Transfer menu.  
Download.  
25  
T-60 Operator's Manual  
Operation:  
Run program:  
Keystroke:  
Description:  
Run the program on the Model  
T-60.  
F1 (T-60)  
26  
Screen Editor  
Editor Capabilities  
Screen Editor  
This Chapter briefly describes the operation of the T-60’s built-in screen  
editor. For a detailed description of the built-in screen editor, refer to the  
EMERSON EMC BASIC PROGRAMMING GUIDE. This editor allows the  
programmer to edit programs directly on the T-60’s screen without a PC  
attached. This feature is most useful for program debug or for constructing  
and modifying short programs. We recommend that you utilize the  
ApplicationBuilder to generate more substantial programs. The  
ApplicationBuilder will shorten your development time, give you much more  
accurately generated BASIC code, and provide a means of storing,  
documenting and cataloging your programs.  
Editor Capabilities  
The built-in screen editor has a complete set of features which allow the  
programmer to develop programs directly on the T-60’s screen. Operation of  
the editor requires the connection of an external PC-XT keyboard (see section  
“Getting Started”). Once the keyboard is connected, you can access every  
programmable function in the T-60. The editor capabilities center around the  
T-60’s 8 line by 40 character display. It has a built-in 50 line scroll buffer  
which can be used to view sections of programs (or entire programs if they  
are short enough). The editor has the following feature set:  
Line oriented editor - change a line by over-typing on it, press ENTER and  
it is modified in the BASIC program.  
78 character line capability. The editor can edit lines longer than the  
screen width. If you keep typing after the first 40 characters, the editor will  
insert a “¦” character at the end of the current line and the beginning of the  
next line. You may continue typing on the next line. The “¦” characters do  
not consume space in your program memory.  
Full cursor control: Up, Down, Left, Right, Page-Up, Page-Down, Home,  
End, Insert, Backspace, and Delete  
Special functions: Control-Y stop program execution and return to the  
editor; Control-T Delete to end of line.  
Active function keys:  
F1  
F2  
F3  
F4  
F5  
F6  
RUN  
LIST  
REMOT  
CONT  
AUTO  
EDIT  
¬
(remote on/off *)  
¬
¬
* Useful for uploading and downloading programs with programs other than  
the ApplicationBuilder. See the REMOTE Statement in the EMERSON  
EMC BASIC PROGRAMMING GUIDE.  
NEW command erases the contents of the editor memory.  
27  
T-60 Operator's Manual  
DELETE command erases sections of the program by line number.  
RENUM allows the entire program or portions of the program to be  
renumbered.  
LIST lists all or sections of the program to the screen.  
LLIST can list all or sections of the program to the printer.  
Help Key  
The T-60 is equipped with a powerful HELP feature. By pressing the HELP  
key on the T-60’s front panel or F10 on the IBM keyboard while in the BASIC  
Interpreter Screen Editor (not running a program), the following screen  
appears:  
Figure 12  
Help Screen  
The HELP screen consists of three basic sections:  
1. TOP of screen. Function keys F7, F8, and F9 scroll through the lists of  
available commands for the T-60. F7 generates a list of commands. By  
pressing the cursor keys, a command will be highlighted. Pressing Enter  
selects the command and displays the help syntax on the screen. F8 and F9  
scroll through the list of commands in alphabetical order.  
2. MID screen. 5 lines of text which describe the COMMAND that the cursor  
was placed on prior to pressing the HELP key, and an example of it’s  
SYNTAX.  
28  
Screen Editor  
Editor Capabilities  
3. FUNCTION keys. Six function keys are active during the help system.  
These keys perform the following functions:  
COM1  
COM2  
SYS  
Displays the buffers and status of COM1.  
Displays the buffers and status of COM2  
Displays system related status.  
Displays 8-bit I/O positions and allows the operator to  
change them.  
I/O  
LITE  
ON  
OFF  
Select LCD backlight auto shutdown, ON, or OFF.  
Leaves the backlight on at all times.  
Leaves the backlight off at all times.  
AUTO  
Turns backlight off after 10 minutes if no activity occurs such as  
program execution or a key press. The backlight comes back on  
as soon as a key is pressed.  
EXIT  
Press this key to leave the HELP system.  
Try the HELP system. Type GOTO and back the cursor up with the or -  
cursor keys until the cursor is underneath one of the characters of the GOTO  
statement. Press HELP. The help screen will display a brief description of  
GOTO. Press EXIT to return to the BASIC Interpreter.  
The HELP key is treated differently when the BASIC Interpreter is running  
a program. When running a BASIC program, the HELP key becomes a  
function key, F10. For example, ON KEY (10) GOSUB T-60 will generate an  
interrupt subroutine call to location 1000 when the HELP key is pressed.  
Think of the HELP key as a “pre-labeled” function key, F10. By keeping  
track of the operational status of your program you can generate context  
sensitive HELP for your application. For example, by providing a variable  
named HELP which gets updated whenever the screen contents change, the  
subroutine which responds to the HELP key can examine this variable and  
print a specific message out to the user which instructs the user what to do at  
any given time.  
Examine the demo programs supplied with the T-60. These programs make  
use of the function key interrupts, and in particular, the F10 or HELP  
interrupt.  
29  
T-60 Operator's Manual  
30  
Application Examples  
Serial Communications made Simple  
Application Examples  
This chapter demonstrates a few of the many applications possible with the  
T-60. Perhaps the best way to think of the T-60 is as an industrial controller  
with an integrated operator interface and very capable I/O. In many systems  
the T-60 can provide the entire system control. In others, intelligent  
controllers such as EMERSON EMC DX series positioning servo drives with  
integrated motor drivers perform the motion control while the T-60 performs  
the man-machine interface and overall orchestration. In all, the T-60 is as  
“smart” as you need to make it. The ApplicationBuilder and the EMERSON  
EMC BASIC can perform some powerful control functions.  
Communicating with the Operator  
Most applications require some sort of man-machine interface. During set-up  
it may be necessary to allow a significant number of parameters to be  
adjusted. During machine operation, it is often desirable to display status  
information and limit the operator’s ability to change crucial process  
parameters. The T-60 is extremely capable of providing this flexibility, and it  
is especially easy to program into the T-60.  
Our first example program is NUMBER.BLD. Load the program into the  
ApplicationBuilder (if you are not familiar with the ApplicationBuilder,  
please refer to “ApplicationBuilder” section). NUMBER.BLD is REALLY  
simple... it asks for a numeric entry from the operator, and re-displays it on  
the screen in another location. Go ahead, try it.  
Notice that the operator entry is performed in a calculator-like fashion. A  
default value is displayed on screen. The first key that you press clears the  
data entry area and allows you to edit data with the left and right arrow keys  
or the insert and delete keys. When you press enter, the data is stored. The  
PSEUDOCODE used to generate this function is the GET NUMBER  
pseudocode. The ApplicationBuilder utilizes the CALL NINPUT BASIC  
statement to construct this entry. The ApplicationBuilder simply calls this  
function to perform data entry.  
The number you have entered is printed out on screen in three different  
character sizes. PUT NUMBER places regular size characters on screen.  
This function is performed by positioning the cursor with the POS command  
and using PRINT. PUT LARGE NUMBER and PUT HUGE NUMBER  
places large (20 characters by 4 lines) or huge (10 characters by 2 lines) on  
screen. These pseudocodes are implemented by the CALL BANNER BASIC  
function.  
Performing data entry and data display with the ApplicationBuilder is about  
as easy as using a very basic word processor. Use GET NUMBER to get data  
and use PUT NUMBER or PUT TEXT to place information on the screen.  
Serial Communications made Simple  
The real power of the T-60 starts demonstrating itself when I/O is used. The  
ApplicationBuilder file SERIAL.BLD demonstrates simple serial  
communications between the T-60 and a serial device (in this case the  
ApplicationBuilder’s Terminal Emulator).  
31  
T-60 Operator's Manual  
Load and convert SERIAL.BLD into a BASIC file (F8 function). Load it into  
the T-60. Now, enter the terminal emulator (ALT-M then type T). Press the  
RUN (F1) softkey on the T-60. You will be asked a question on your PC’s  
screen. Answer it and press Enter. Watch what happens.  
The ApplicationBuilder utilizes COM: PUT TEXT pseudocode to transmit  
serial data. Actually, COM: PUT TEXT is converted into the PRINT #  
BASIC statement to perform serial I/O. Data is gathered into a string  
variable and output directly to the port in a single instruction. The COM:  
INIT pseudocode generates a CONFIG # BASIC statement to initialize the  
I/O. The complexities of the CONFIG statement are hidden from the  
programmer with the simplicity of the pseudocode.  
Parallel I/O Made Simple  
If you thought Serial I/O was easy wait until you take a look at Parallel I/O.  
The T-60 has 8 parallel I/O lines built into it. The ApplicationBuilder has a  
host of I/O pseudocodes. To look at them, press F5 then press the I key. This  
will display a list of available I/O pseudocodes.  
An example program which sequences I/O bits one at a time is on your  
ApplicationBuilder diskette: IO.BLD. Try loading it and running it. This  
program uses on-screen messages to tell you about itself.  
EMERSON EMC DX Drive Demo Program  
Please read the first part of  
This program (DX-COM.BLD) was written to demonstrate the capability of  
the DX.-COM.BLD program.  
There are instructions on how  
the DX Amplifier must be  
setup to operate correctly.  
the T-60 to control a EMERSON EMC DX Drive. The T-60 starts the  
program at power on, and begins communicating with the DX Drive. It then  
allows the user to make simple moves, download sequences, and scale units.  
This program provides a good starting place for understanding how to  
communicate with the EMERSON EMC DX Drives.  
Installation  
Connect the T-60 to the PC and to the DX Drive Amplifier as shown in Figure  
17. T-60’s COM 2 port connects to the PC’s COM 1 or COM 2 port. This  
connection must be made with a NULL MODEM cable. The T-60’s COM 1  
port connects to the DX Drive Amplifier’s serial “B” port.  
You will need a serial communications cable (Model number TIA-XXX), to  
connect a DX Drive to the T-60. Such a cable can be obtained from  
EMERSON EMC in three standard lengths:  
Part Number  
TIA-010  
TIA-025  
Length  
10 FT  
25 FT  
50 FT  
TIA-050  
32  
Application Examples  
Parallel I/O Made Simple  
Figure 13  
Installation  
When power is turned on to the T-60 and the DX Drive, the  
ApplicationBuilder program will test for communication’s integrity, and  
begin execution. If the T-60 is unable to establish communications, check the  
following items:  
Verify that the DX Drive Amplifier is on and in working order.  
A power-on sequence must be setup which automatically starts executing  
on power up.  
Verify the connections made between the drive and the T-60.  
33  
T-60 Operator's Manual  
Using The T-60 With One or More DX Drives  
Connecting the T-60 to the DX drive(s) is very simple when the proper cables  
are used. The Figure below illustrates the required cables and what they  
should be connected to. The PC’s COM1 or COM2 is connected to COM2 on  
the T-60. Note that the cable used for this connection is a NULL MODEM  
cable, and can be obtained from EMERSON EMC. COM1 on the T-60 is  
connected to the DX drive via a TIA cable also available from EMC.  
Figure 14  
Installation - T-60 W/More  
Than One DX Drive  
Baud rates and setup  
The build software should be able to communicate with the T-60 without  
deviation from the default comm parameters. The DX drive serial parameters  
must be set up as desired along with the axis id. These parameters will be  
matched by the COM initialization pseudo-command provided by the builder  
software.  
34  
Application Examples  
Using The T-60 With One or More DX Drives  
DX specific pseudo-commands  
There are 2 pseudo-commands which are used only with the DX drives:  
COM: DX PUT COM port TEXT text STRING RESPONSE response  
COM: DX SELECT AXIS axis  
These commands are fully described in the builder software and illustrated in  
the included example programs.  
35  
T-60 Operator's Manual  
36  
T-60 Basic Programming Language  
Variables, Constants, and Strings  
T-60 Basic Programming Language  
This chapter gives an overview of the capabilities of the EMERSON EMC  
BASIC. The BASIC language integrated into the T-60 has been custom  
designed and optimized for speed of execution and ease of use with the  
specific hardware features of the T-60. A complete description of the syntax  
is available in the EMERSON EMC BASIC PROGRAMMING GUIDE. This  
guide is provided with the T-60 and is available from EMERSON EMC or  
your EMERSON EMC DISTRIBUTOR.  
Variables, Constants, and Strings  
The EMERSON EMC BASIC has a range of numeric and string variable and  
constant types. Variable names may be up to 8 characters long. The  
characters allowed in a variable name are letters, numbers, and the decimal  
point. The first character in the variable name must be a letter. Special type  
declaration characters are also allowed. The types and their dynamic ranges:  
Type:  
Symbol: Description:  
Float!  
(or none) Floating point numeric variables and constants.  
Positive or negative numbers represented in  
exponential form (similar to scientific notation).  
A floating-point constant consists of an optionally-  
signed integer or fixed-point number (the mantissa),  
followed by the letter E and an optionally signed  
integer (the exponent). The allowable range for  
floating-point constants is 0.8388607X10-19 to  
-0.8388607X1014. For example:  
235.988E-7 = .0000235988  
2359E6 = 2359000000  
Integer  
%
Integer numeric variables and constants. Whole  
numbers between -32768 and +32767. They do not  
contain decimal points.  
Double-  
Precision  
Integer  
&
Double precision variables and constants. Whole  
numbers between -2147483648 and +2147483647.  
They do not contain decimal points.  
String  
$ String variables and constants. A string can consist  
of up to 127 alphanumeric characters.The default type  
for a numeric variable name is single-precision.You  
should be very careful when making conversions between  
integer, single-precision, and double-precision integers  
variables, rounding errors may occur.  
Double-precision integers are useful for moderately fast math functions.  
Many different types of machine controllers require double precision numeric  
ranges for their input. Double-precision integers were implemented  
primarily for this purpose.  
37  
T-60 Operator's Manual  
Array Variables  
An array is a group or table of values referenced by the same variable name.  
Each element in an array is referenced by an array variable that is a  
subscripted integer or an integer expression. The subscript is enclosed  
within parentheses. An array variable name has as many subscripts as there  
are dimensions in the array.  
For example,  
V(10)  
references a value in a one-dimensional array, while  
T(1,4)  
references a value in a two-dimensional array.  
The maximum number of dimensions for an array in EMERSON EMC  
BASIC is 16383. Arrays cannot have a size greater than 32767 bytes. i.e.  
A(8191), b%(16383), and s$(16383) are all valid. A(8192), b%(16384), and  
s$(16384) are all invalid sizes for arrays. See 6.2.4 for a description of  
memory space requirements.  
Multi-dimensional arrays (more than one subscript separated by commas)  
are useful for storing tabular data. For example, an array dimensioned with  
DIM A(2,5) could be used to represent a two-row, five-column array such as  
the following:  
Column  
1
2
3
4
5
Row 1  
Row 2  
10  
60  
20  
70  
30  
80  
40  
90  
50  
100  
In this example, element A(2,3)= 80 and A(1,4)= 406.3  
Arithmetic Operation  
The following are the arithmetic operators recognized by EMERSON EMC  
BASIC. They appear in order of precedence.  
Operator:  
^
-
Operation:  
Exponentiation  
Negation  
*
/
Multiplication  
Floating-point Division  
Modulus  
MOD  
+
-
Addition  
Subtraction  
Operations within parentheses are performed first. Inside the parentheses,  
the usual order of precedence is maintained. Two consecutive operators must  
be separated by parentheses.  
38  
T-60 Basic Programming Language  
Logical Operators  
Relational Operations  
Relational operators let you compare two values. The result of the  
comparison is either true (-1) or false (0). This result can then be used to  
make a decision regarding program flow.  
=
<>  
<
>
Equality  
Inequality  
Less than  
Greater than  
Less than or equal to  
X = Y  
X <> Y  
X < Y  
X > Y  
X <= Y  
<=  
>=  
Greater than or equal to X >= Y  
The equal sign is also used to assign a value to a variable.  
When arithmetic and relational operators are combined in one expression,  
the arithmetic is always performed first:  
X+Y < (T-1)/Z  
This expression is true if the value of X plus Y is less than the value of T-1  
divided by Z.  
Logical Operators  
Logical operators perform tests on multiple relations, bit manipulation, or  
boolean operations. The logical operator returns a bit-wise result which is  
either true (not zero) or false (zero). In an expression, logical operations are  
performed after arithmetic and relational operations. The following table  
lists the availabe logical operators.  
Operator:  
NOT  
AND  
Operation:  
Logical negation  
Logical AND  
OR  
XOR  
Logical OR  
Logical exclusive OR  
Just as the relational operators can be used to make decisions regarding  
program flow, logical operators can connect two or more relations and return  
a true or false value to be used in a decision. For example:  
IF D<200 AND F<4 THEN 80  
IF I>10 OR K<0 THEN 50  
IF NOT P THEN 100  
39  
T-60 Operator's Manual  
It is possible to use logical operators to test bytes for a particular bit pattern.  
For instance, the AND operator may be used to mask all but one of the bits of  
a status byte at a machine I/O port. The OR operator may be used to merge  
two bytes to create a particular binary value. The following examples  
demonstrate how the logical operators work:  
Example  
Explanation  
63 AND 16=16  
10 OR 10=10  
63=binary 111111 and 16=binary 10000, so 63 AND 16=16  
10=binary 1010, so 1010 OR 1010=1010(10)  
NOT X = -(X+1)  
The two’s complement of any integer is the bit  
complement plus one.  
Functional Operators  
A function is used in an expression to call a predetermined operation that is  
to be performed on an operand. BASIC has intrinsic functions that reside in  
the system, such as SQR (square root) or SIN (sine).  
BASIC also allows user-defined functions written by the programmer. See  
the DEF FN statement in the EMERSON EMC BASIC PROGRAMMING  
GUIDE.  
The CALL instruction allows access to T-60 machine specific features such as  
special screen functions or option board functions. The CALL instruction  
may have optional parameters associated with it. Refer to the CALL  
instruction in the EMERSON EMC BASIC PROGRAMMING GUIDE.  
String Operators  
To compare strings, use the same relational operators used with numbers:  
Operator  
Meaning  
=
<>  
<
Equal to  
Unequal  
Less than  
>
<=  
>=  
Greater than  
Less than or equal to  
Greater than or equal to  
The BASIC Interpreter compares strings by taking one character at a time  
from each string and comparing their ASCII codes. If the ASCII codes in each  
string are the same, the strings are equal. If the ASCII codes differ, the lower  
code number will precede the higher code. If the interpreter reaches the end  
of one string during string comparison, the shorter string is said to be  
smaller, providing that both strings are the same up to that point. Leading  
and trailing blanks are significant.  
40  
T-60 Basic Programming Language  
String Operators  
For example:  
“AA”  
<
=
<
<
“AB”  
“FILENAME”  
“SMYTHE”  
“FILENAME”  
“SMYTH”  
B$  
“9/12/78” where B$ = “8/12/78”  
String comparisons can also be used to test string values or to alphabetize  
strings. All string constants used in comparison expressions must be enclosed  
in quotation marks.  
Strings can be concatenated by using the plus (+) sign. For example:  
10 A$=”FILE”:B$=”NAME”  
20 PRINT A$+B$  
30PRINT “NEW” + A$+B$  
RUN  
FILENAME  
NEW FILENAME  
41  
T-60 Operator's Manual  
EMERSON Basic Statements, Commands, and  
Functions  
The following is an alphabetized list of statements commands and functions  
available in the EMERSON EMC BASIC. The EMERSON EMC BASIC  
PROGRAMMING GUIDE contains a detailed description of the each of these  
commands. Eason Technology is constantly adding new capability to the  
T-60, please contact the factory or your Eason Technology Distributor for the  
latest copy of the EMERSON EMC BASIC PROGRAMMING GUIDE. Copies  
of the guide are also available on diskette. You can use the  
ApplicationBuilder Editor to load and search for the description of a  
command without having to search for a manual.  
ABS  
ASC  
ATN  
Absolute value  
ASCII to number  
Arctangent  
INKEY$  
INP  
INPUT  
Read keyboard (returns string)  
Input from 8-bit I/O  
Get user input  
AUT  
BIN  
BIN  
CALL  
Auto line number  
INPUT#  
INPUT$  
INSTR  
INT  
IO24  
KEY  
KEY(n)  
LABEL  
LEFT$  
LEN  
INPUT  
LINE INPUT  
LISTDisplay  
LLIST  
LOG  
LOCK  
LPRINT  
LPRINT USING  
MID$  
Input from comm port  
String input  
Search for string  
Binary to decimal  
Decimal to binary  
T-60 special function  
Print large characters  
Graphics box draw function  
Clear graphics screen  
Display text with help text  
Draw graphics line  
Formatted numeric string conversion  
Formatted numeric setup  
Formatted numeric input  
Formatted numeric entry  
Return color of graphics point  
Scan the keyboard return keycode  
Draw graphics pixel  
Number to ASCII  
Truncate to whole number  
Specify an I/O bit pattern to trap on  
Function key statements  
Function key interrupts  
Line label  
Left characters of a string  
Length of string LINE  
Input until Enter  
#Line input from comm port  
Lines on screen  
Print lines  
Natural log  
Secure program from edit,view  
Write to printer  
CALL BANNER  
CALL BOX  
CALL GCLS  
CALL HELP  
CALL LINE  
CALL NFORMAT  
CALL NSETUP  
CALL NKEY  
CALL NINPUT  
CALL POINT  
CALL SCANKEY  
CALL SET  
CHR$  
CLEAR  
CLS  
COM(n)  
CONFIG  
CONT  
Clear variables  
Clear screen  
Communications trapping  
Communications settings  
Continue  
Formatted LPRINT  
Substring operations  
Clear program  
Octal to decimal  
Decimal to octal  
NEW  
OCT  
OCT$  
COS  
Cosine  
Cursor row  
Cursor column  
Data storage  
Define function  
Millisecond delay  
Delete program lines  
Dimension array  
Edit program lines  
End of program  
Erase arrays  
Error code  
Line number with an error  
Simulate error  
Exponentiate  
ON COM(n)  
ON IO24  
ON KEY(n)  
ON TIMER(n)  
ON ERROR GOTO  
ON...GOSUB  
ON...GOTO  
OUT  
OUT XOR  
OUT AND  
OUT MAP  
OUT OR  
POS  
Interrupt on comm port  
Interrupt on I/O bit pattern  
Interrupt on function key  
Interrupt on timer  
CSRCOL  
CSRROW  
DATA  
DEF FN  
DELAY  
DELETE  
DIM  
EDIT  
END  
ERASE  
ERR  
ERL  
Interrupt on error  
GOSUB to list of line numbers  
GOTO list of line numbers  
Output to 8-bit I/O  
Logical exclusive OR to 8-bit I/O  
Logical AND to 8-bit I/O  
Set/clear bits on 8-bit I/O  
Logical OR to 8-bit I/O  
Position Cursor  
ERROR  
EXP  
POWER RESUME  
PRINT  
Auto startup  
Write to display  
FIX  
FOR  
NEXT  
FRE  
Truncate to whole number  
FOR-NEXT loops  
FOR-NEXT loops  
PRINT USING  
PRINT #  
PRINT # USING  
READ  
Formatted PRINT  
Write to comm port  
Formatted PRINT #  
Read data  
Free Space  
GOSUB  
GOTO  
HEX  
HEX$  
IF  
Subroutine call  
REM  
Comment  
Jump to line number  
Hexadecimal to decimal  
Decimal to hexidecimal  
Conditional Statement  
Read keyboard (returns number)  
REMOTE  
RENUM  
REPEAT  
UNTIL  
Host computer control  
Update line numbers  
REPEAT-UNTIL loops  
REPEAT-UNTIL loops  
Re-read data statements  
INKEY  
RESTORE  
42  
T-60 Basic Programming Language  
EMERSON Basic Statements, Commands, and Functions  
RESUME  
RETURN  
RIGHT$  
RND  
RS422  
RUN  
SGN  
SIN  
SPACE$  
SQR  
STOP  
Continue after error  
Exit GOSUB  
Substring operations  
Random number  
RS422 port control  
Start program  
Get sign of number  
Sine function  
Generate spaces  
Square root  
STRING$  
TAB  
TAN  
Multiple copies  
Tab spaces  
Tangent  
Internal timer  
Set/retrieve time  
Initialize timer interrupt  
Trace ON/OFF  
String to number  
Report software version  
WHILE-WEND loops  
WHILE-WEND loops  
TIME  
TIME$  
TIMER  
TRACE  
VAL  
VER  
WHILE  
WEND  
Halt program  
STR$  
Convert to string  
43  
T-60 Operator's Manual  
44  
64K Memory Option  
Adding Memory Options to the T-60  
64K Memory Option  
The M02 option adds 32K bytes of storage to the T-60’s battery-backed up  
memory to bring the total memory up to 64K bytes. Larger programs and  
more data can be stored in this additional memory. In addition, nonvolatile  
storage registers can also be used when this option is added. 480 numeric  
registers, floating point, fixed precision, and integers (in any combination), as  
well as 16 string registers (128 bytes each) are available for storing  
seldom-changed program constants and data. Power failure, program  
loading, variable clearing, or gosub stack clearing will not affect the data  
stored in these registers.  
You can tell if the M02 option has been installed in your unit by pressing the  
HELP key when the T-60 is not running a program (in command mode). By  
pressing the SYS key, the amount of memory installed will be indicated on  
the screen. It should read 64K. The amount of free memory will vary  
depending upon data and programs loaded. With no data or no programs  
loaded, the free memory should be 52735 bytes.  
The M02 option adds access to a pre-dimensioned array called NVOL. NVOL  
can contain up to 512 floating point, short integer or long integer variables.  
In addition, the M02 option adds access to a pre-dimensioned string array  
called NVOL$. NVOL$ allows access of up to sixteen 128 byte string array  
variables. The M02 option is field installable.  
Adding Memory Options to the T-60  
Follow these steps to upgrade the T-60 to 64K of RAM:  
1. Save the contents of the program memory. Use a PC and the  
ApplicationBuilder program to do this. Changing the internal memory  
will require resetting the system, thereby erasing the contents of all  
memory.  
2. Remove power connections to the unit.  
Disconnect power from the T-60 before attempting to install ram. You may  
cause damage to the unit if the power is not disconnected.  
3. Carefully unscrew the top two screws and each of the screws on the side  
of the unit.  
4. Lay the unit on its back on a soft, clean surface.  
Check the serial number of your T-60. If it begins with “ETI”, please go to  
section B.Otherwise, proceed here with section A.  
Section A  
1. Remove the front panel by carefully lifting it off the unit and  
disconnecting the two pin connector for the backlight cable (J6, see  
diagram).  
45  
T-60 Operator's Manual  
2. Position the front panel to the side of the unit, being careful not to stress  
the internal cables.  
3. To install an MO2 option, insert a 256Kbit RAM (120 nsec, JDEC 32 pin)  
in location U9. Be sure that PIN 1 (location on RAM with notch or dot) is  
facing down (towards the center of the unit). Note carefully the position of  
U9 and the orientation of the RAM in the diagram. Check carefully for  
bent or damaged pins.  
Improper orientation of U9 will destroy the RAM, and possibly cause  
damage to the unit.  
4. Re-connect the backlight cable connector to J6 (see diagram) and replace  
the front panel and screws.  
5. Connect an IBM KEYBOARD to the KEYBOARD connector. Make sure  
that the keyboard is a type which is compatible with an IBM PC XT (not  
AT).  
6. Re-connect power to the unit. Press the CTRL, ALT and DEL keys on the  
IBM KEYBOARD simultaneously. This will reset the unit and normal  
operation will begin.  
7. Check the installation by pressing HELP on the T-60 followed by F4  
(SYS). The memory option should show 64K.  
8. If the memory option only shows 32K, or the display does not come up  
displaying the sign-on message, REMOVE POWER IMMEDIATELY.  
Remove the cover and recheck the installation of U9.  
Figure 15  
Top of Board Inside T-60  
Section B  
1. Remove the front panel by carefully lifting it off the unit and  
disconnecting the two pin connector for the backlight cable (J10, see  
diagram).  
2. Position the front panel to the side of the unit, being careful not to stress  
the internal cables.  
46  
64K Memory Option  
Adding Memory Options to the T-60  
3. To install an MO2 option, insert a 256Kbit RAM (120 nsec, JDEC 32 pin)  
in location U9. Be sure that PIN 1 (location on RAM with notch or dot) is  
facing down (towards the center of the unit). Note carefully the position of  
U9 and the orientation of the RAM in the diagram. Check carefully for  
bent or damaged pins. If you are installing sn MO3 option, repeat the  
procedure in locations U45 and U46.  
Improper orientation of U9, U45, or U46 will destroy the RAM and possibly  
cause damage to the unit.  
4. Re-connect the backlight cable connector to J10 (see diagram) and replace  
the front panel and screws.  
5. Connect an IBM KEYBOARD to the KEYBOARD connector. Make sure  
that the keyboard is a type which is compatible with an IBM PC XT (not  
AT).  
6. Re-connect power to the unit. Press the CTRL, ALT and DEL keys on the  
IBM KEYBOARD simultaneously. This will reset the unit and normal  
operation will begin.  
7. Check the installation by pressing HELP on the T-60 followed by F4  
(SYS). The memory option should show 64K if you installed an MO2;  
128K if you installed an MO3.  
8. If the memory option only shows 32K, or the display does not come up  
displaying the sign-on message, REMOVE POWER IMMEDIATELY.  
Remove the cover and recheck the installation of U9, U45 and U46.  
Figure 16  
Top of Board Inside the T-60  
47  
T-60 Operator's Manual  
Changing ROMS in the T-60  
Follow these steps to change a program ROM in the T-60:  
1. Save the contents of the program memory. Use a PC and the  
ApplicationBuilder program to do this.  
2. Remove power connections to the unit.  
3. Carefully unscrew the top two screws and each of the screws on the side  
of the unit.  
4. Lay the unit face down on a soft, clean surface.  
5. Remove the rear cover by carefully lifting it off the unit.  
6. Position the cover to the side of the unit, being careful not to stress the  
internal cables.  
7. Remove the ROM located at the top of the main board (top being closest  
to the display). Note the orientation of PIN 1 on the device (see diagram).  
8. Insert the new ROM in location U15. Be sure that PIN 1 (location on  
ROM with notch or dot) is facing down (towards the center of the unit).  
Check carefully for bent or damaged pins.  
Improper orientation of U15 will destroy the ROM and possibly cause  
damage to the unit.  
9. Re-attach the backlight cable (2 pin cable) to J6 (near U15, see diagram).  
10. Replace the cover and screws.  
11. Connect an IBM KEYBOARD to the KEYBOARD connector. Make sure  
that the keyboard is a type which is compatible with an IBM PC (not AT).  
12. Re-connect power to the unit. Press the CTRL, ALT, and DEL keys on the  
IBM KEYBOARD simultaneously. This will reset the unit, and normal  
operation will begin.  
Figure 17  
Top of Board Inside the T-60  
48  
Changing the Battery in a T-60  
Changing ROMS in the T-60  
Changing the Battery in a T-60  
Follow these steps to change the battery for the non-volatile RAM in a T-60:  
1. Save the contents of the program memory. Use a PC and the  
ApplicationBuilder program to do this. Changing the battery may reset  
the system if you wait too long to change it or don’t change it quickly,  
thereby erasing the contents of all memory.  
2. Remove power connections to the unit.  
Disconnect power from the T-60 before attempting to change the battery.  
Hazardous voltages exist inside the unit with power connected. Personal  
injury or death may result if the power is not disconnected.  
3. Carefully unscrew the top two screws and each of the screws on the side  
of the unit.  
4. Lay the unit face down on a soft, clean surface.  
5. Remove the rear cover by carefully lifting it off the unit.  
6. Position the cover to the side of the unit, being careful not to stress the  
internal cables.  
7. To remove the old battery, insert a small screwdriver between the edge of  
the battery and the battery holder near the battery clip (see diagram).  
Push gently and the battery should slide out.  
Figure 18  
Battery Replacement  
8. Before installing the new battery, press down on the battery clip to make  
sure that there will be good retention force when the battery is in place.  
Also make sure that all contact surfaces are clean. As noted on the  
battery clip, make sure that the positive (+) side of the battery is up.  
Slide the battery under the clip and into the battery holder. Make sure  
that the battery is held firmly in place.  
Improper orientation of the battery will not allow the battery backed RAM to  
function and your memory will cease to be non-volatile. However, this will  
not damage the battery or the controller; just turn the battery over and  
continue with the installation procedure.  
49  
T-60 Operator's Manual  
9. Replace cover and cover screws.  
10. Reconnect power to the unit.  
11. If you notice any problems that can’t be explained by the battery being  
installed upside down (no non-volatile memory), disconnect power and  
connect an IBM KEYBOARD to the KEYBOARD connector. Make sure  
that the keyboard is a type which is compatible with an IBM PC XT (not  
AT).  
12. Re-connect power to the unit. Press the CTRL, ALT, and DEL keys on the  
IBM KEYBOARD simultaneously. This will reset the unit, and normal  
operation will begin. Call Emerson EMC if any problems persist.  
50  
Real Time Clock  
Adding the Real -Time Clock to the T-60  
Real Time Clock  
The CLK option adds a battery backed real time clock to the T-60. Once  
installed you can set the date, day of the week and time with a single  
statement: CALL WRCLOCK. You can read the day, day of the week, and  
the time with another single statement: CALL RDCLOCK. Refer to the  
EMERSON EMC BASIC USERS GUIDE for the programming syntax for  
these new commands. The CLK option’s battery is integrated into a  
removable module which has a sealed internal lithium battery which is  
designed to last 10 years. The CLK option is field installable.  
Adding the Real -Time Clock to the T-60  
Follow these steps to add a real-time clock (CLK option) to the T-60:  
1. Save the contents of the program memory. Use a PC and the  
ApplicationBuilder program to do this.  
2. Remove power connections to the unit.  
Disconnect power from the T-60 before attempting to install a CLK Option.  
3. Carefully unscrew the top screws and each of the screws on the side of  
the unit.  
4. Lay the unit on its back on a soft, clean surface.  
5. Remove the front panel by carefully lifting it off the unit and  
disconnecting the 2 pin connector for the backlight cable (J6, see  
diagram).  
6. Position the cover to the side of the unit, being careful not to stress the  
internal cables.  
7. Insert the CLK option in socket U7. Be sure that PIN 1 (location on the  
CLK with notch or dot) is facing down (towards the center of the unit, see  
diagram). Check carefully for bent or damaged pins.  
Improper orientation of the CLK will destroy it, and possibly cause damage  
to the unit.  
Figure 19  
Top of Board Inside the T-60  
51  
T-60 Operator's Manual  
8. Reconnect the backlight cable connector and replace the front panel and  
screws.  
9. It may be necessary to set the real-time clock before it can be used. Refer  
to the BASIC User’s Manual for instructions on how to set the clock.  
52  
Event Driven Software  
Adding the Real -Time Clock to the T-60  
Event Driven Software  
The EMERSON EMC T-60 Event Driven Software allows the T-60 to react  
quickly to external events, without taxing the overhead of the imbedded BASIC  
programming language. The Event Software allows the T-60 to scan an input,  
react to it, and immediately output data to the A/D’s or the 8 bit I/O port.  
The input or source can be derived from bits 0 through 10 of the 8 I/O, an  
analog input voltage from an option module (optional), or from a counter on  
the counter option module (also optional). The Event Software is table  
driven. The program enters data into multiple rows in this table (see Figure  
). Each of these rows is called a “Schedule”. When the Event Manager  
software is activated, it reads data from the source and compares it to low  
and high compare values that were programmed into each schedule. When  
the data read from the source is within the range specified for a given  
schedule, the Event Manager automatically outputs I/O values, optional A/D  
values, and can GOSUB to a BASIC subroutine. The BASIC subroutine can  
determine which event has occurred by reading Event Manager data. Note  
that the I/O operations are optional. For example, an individual schedule can  
be programmed to only output one analog value, leaving the I/O and the  
other analog values unchanged.  
If the source is from I/O or an optional analog input, the comparisons are  
performed with 16 bit integer mathematics, giving the greatest degree of  
flexibility possible (overlapping events and 32 possible schedules). If the  
source is from the optional counter, the comparisons are performed with 32  
bit integer mathematics, limiting the events to non-overlapping regions and  
16 possible schedules. The M02 option is required for the operation of the  
EVENT DRIVEN SOFTWARE.  
Each schedule is comprised of a 32 byte record. There are up to 32 schedules  
available (16 for the optional counter). Individual elements within the table  
represent a comparison values which are specified as “LOW” and “HIGH”. If  
the event data falls within the range specified by LOW and HIGH, the  
previous event data is compared to see if the data was previously within the  
same region. If they are different (meaning a change has been encountered),  
a change of events has occurred. If the enable bytes for I/O and DAC’s are  
true (greater than 0), the corresponding I/O or DAC is updated. If the BASIC  
interrupt system has been enabled to look for changes with the ON EVENT  
and EVENT ON statements, a BASIC interrupt can occur once every event  
change.Schedule 0 represents the left-over or unclaimed regions. There may  
be many unclaimed regions, or none. By programming schedule 0, you may  
set up data default output data which will always be refreshed when the  
event system leaves a specific event, and has no other specified event to go to.  
53  
T-60 Operator's Manual  
Event Data Elements:  
Figure 20  
Event System - One Schedule  
Element  
The EVENT SYSTEM is not enabled until the EVENT ON statement is  
issued. EVENT ON may be used without a corresponding ON EVENT  
statement, thereby avoiding the use of the T-60’s interrupt system. See the  
example in the end of this section for the proper use of the EVENT ON  
syntax.  
54  
Hardware Reference  
Electrical /Mechanical Specifications  
Hardware Reference  
Electrical /Mechanical Specifications  
Memory:  
32K bytes battery backed RAM standard, 64K bytes  
optional  
Communications:  
Two RS232C ports, XON / XOFF handshaking capability  
COM 1 is configurable as RS232, RS422, or RS485.  
Optically isolated.  
I/O:  
8 bit parallel I/O; optically isolated -0.5 to +30V input,  
pulled up to +5V by 22K resistor Open collector output,  
sink 30 mA Industry standard PB-8 compatible.  
Keyboard  
IBM-PC XT compatible  
Connector:  
Display:  
Size:  
High contrast Super-Twist LCD (liquid crystal display)  
8 lines by 40 characters  
5 x 8 dot matrix; 0.095 x .15 (2.40 mm x 3.84 mm)  
0.019" x 0.019" (0.48 mm x 0.48 mm)  
Electro-luminescent panel with “auto-shutdown”  
feature Graphics capability.  
Characters:  
Dot size:  
Backlight:  
Keyboard:  
30 large, full-travel keys, rubber elastomer type  
Context sensitive HELP key available  
Help function:  
Functions:  
9 programmable function keys  
Cursor, insert, delete, alpha, and print keys  
Power:  
9V to 30V DC 6 Watts maximum.  
1 Amp power-on inrush current.  
Weight:  
4.2 lbs (1.9 Kg)  
Environment:  
+32 to +122° F (0 to +50° C)  
5% to 95% relative humidity (non-condensing)  
Designed to NEMA 4 (water-tight) and NEMA 12 (dust-  
tight) specifications.  
Mounting:  
Panel mount or flat surface mount (hardware included)  
Rugged, cast front housing  
Physical size:  
8.5"H X 8.5"W X 2.44"D  
55  
T-60 Operator's Manual  
56  
Connector Pin-Out Specifications  
Electrical /Mechanical Specifications  
Connector Pin-Out Specifications  
Power / RS422 Connector:  
Pin  
8
7
Function:  
SHIELD  
TX A  
6
5
TX B  
RX A  
4
3
2
1
RX B  
LOGIC GROUND  
DC IN +  
DC IN -  
I/O Connector:  
Pin:  
19  
17  
15  
13  
11  
9
Function:  
+5V *  
I/O 0  
I/O 1  
I/O 2  
I/O 3  
I/O 4  
I/O 5  
7
5
3
I/O 6  
I/O 7  
1
UNUSED  
*
(100 MA Load Maximum) All even numbered pins are connected to logic  
ground.  
Keyboard Connector:  
Pin:  
Function:  
1
2
3
4
5
KEYBOARD CLOCK  
KEYBOARD DATA  
KEYBOARD RESET  
+5V  
GROUND  
COM1 and COM2 Pin-Outs:  
Pin:  
Connection:  
HOUSING  
SHIELD  
2
3
5
RS232 RECEIVE (INPUT)  
RS232 TRANSMIT (OUTPUT)  
SIGNAL GROUND  
All other pins not connected.  
57  
T-60 Operator's Manual  
Figure 21  
Physical Dimensions  
58  
PLC Interface Commands Introduction  
PLC Interface Commands  
Introduction  
The EMERSON EMC T-60 Series PLC Interfaces are designed to make many  
of the individual intricacies of the various PLC Interfaces transparent to the  
user. That is to say that reading a register in a Modicon PLC uses the same  
procedure as reading a register in an Omron PLC. This allows a given  
program to be written for one PLC and then used with another PLC just by  
changing the PLC Interface option in your T-60 Series unit. This assumes, of  
course, that both PLC’s have equivalent functionality.  
For example, Modicon and TI treat analog I/O very differently (Modicon  
treats analog I/O as simply another register, whereas TI has separate  
memory locations for registers and analog I/O) so they are accessed  
differently via the T-60 Series.  
Three “calls” are the heart of the PLC communications. They are CALL  
PLCINIT, CALL PLCREAD, and CALL PLCWRITE. These calls can be used  
in any reasonable location within a basic program running in the T-60 or  
T-61 with a PLC Interface option.  
This allows the use of the data in a register, bit status, analog I/O value, or  
any other applicable data available from a PLC in a process or interface  
program in the T-60 Series device.  
For most of the PLC Interface Options, the PLC Interface is on COM1 of the  
T-60 Series device. COM2 retains its default status. The -MOD, -PL5, and  
-SL5 Options have the ability to communicate to the PLC from either COM  
port. In effect, this allows you to hook two PLC’s to each T-60 or T-61. In a  
T-60 , COM2 is still standard RS232C. In a T-61, COM2 can still be  
configured to be RS232C, RS422, or RS485.  
This allows the integration of a PLC and virtually any other serial  
communications device. For example, you can connect a PLC to COM1 and  
another device that uses serial communication (e.g., motion controllers, PC’s,  
serial displays, temperature controllers, etc.) to COM2 and communicate to  
all devices via the T-60 Series interface. In effect, the T-60 Series acts as an  
Operator Interface and an ASCII/BASIC module in one.  
59  
T-60 Operator's Manual  
The tabel below shows the current PLC interface options.  
Table 3  
Inte rfa c e Option  
-MOD  
-GE9  
PLC Protoc ols Supporte d  
Modbus (Modic on)  
GE Se rie s 90 (GE Fa nuc )  
TI305 (GE Se rie s 1) & TI405  
TI505 (Sie m e ns/TI)  
Softwa re Ve rsion  
20-0000X-02-X.XX  
20-0000X-03-X.XX  
20-0000X-04-X.XX  
20-0000X-05-X.XX  
20-0000X-06-X.XX  
20-0000X-07-X.XX  
20-0000X-08-X.XX  
20-0000X-09-X.XX  
20-0000X-10-X.XX  
20-0000X-11-X.XX  
20-0000X-13-X.XX+  
Current PLC Interface Options  
-TI3  
-TI5  
-PL5  
Alle n Bra dle y PLC-5  
Om ron Hostlink  
-OM1  
-PL2  
Alle n Bra dle y PLC-2  
Alle n Bra dle y SLC 500  
IDEC FA-1J\FA2-J  
-SL5  
-ID1  
-MFX  
-SQD  
Mitsubishi FX  
Squa re D SY/MAX  
As mentioned above, the PLC Interfaces all work in a similar, if not identical,  
fashion (the -PL5, -SL5, -ID1, -MFX, and -SQD interfaces are more unique  
than any of the others - refer to the PLC SPECIFIC sections for detailed  
information on how to use these interfaces).  
Initialization of the PLC Interface (setting the proper communication  
parameters and verifying the establishment of the link between the PLC and  
the T-60 or T-61) always occurs with the CALL PLCINIT command. This  
command need only be issued once, usually during the initialization portion  
of your program. Any data that you wish to get from the PLC is retrieved by  
the CALL PLCREAD command. Data that you wish to write in a register,  
memory locations that you wish to define, or I/O bits you wish to set are all  
effected with the CALL PLCWRITE statement.  
The following section describes the CALL PLCINIT, CALL PLCREAD, and  
CALL PLCWRITE commands in general. Most of the PLC Interfaces  
developed so far use the same arguments for similar functionality, no matter  
which Interface is installed. Exceptions are noted in the tables. More specific  
information follows in sections particular to each Interface Option.  
Refer to the section for your PLC to see if the “normal” implementation for a  
given function is different for you PLC. See the PLC and SLC specific  
sections on the -PL5 and -SL5 Options for the CALL PLCREAD and CALL  
PLCWRITE commands for the Allen Bradley PLC-5 and SLC 500 PLC’s as  
they are significantly different from the rest of the interface options.  
60  
PLC Interface Commands CALL PLCINIT Statement  
CALL PLCINIT Statement  
Purpose:  
This command is used to initialize communication with a given PLC of a  
given type. CALL PLCINIT must be issued prior to any other  
communication (reading or writing) to the specified PLC. CALL PLCINIT  
does auto-baud rate detect for some PLC’s and sets up specific  
communications parameters for others. See the section specific to your  
Interface Option for information regarding the initialization parameters for  
that particular system. If the CALL PLCINIT command fails, the T-60 Series  
unit will break your program and generate the error message “PLC link not  
established.” If this occurs, refer to the individual section for your option to  
make sure that the connections and communications configurations are  
correct. If they are OK, check to make sure that you do not have a password  
in your PLC that is not allowing access to the programming port.  
Syntax:  
CALL PLCINIT(  
)
id,cmd  
Comments:  
id specifies the address of the PLC that you wish to initialize. Some PLC’s  
allow addressing of multiple PLC’s, others do not. Refer to your PLC  
Operator’s manuals for information regarding capability and implementation.  
Table 4  
Inte rfa c e Option  
Cm d  
PLC Protoc ol  
Modbus COM1  
GE Se rie s 90  
TI305/405  
PLC Protocol Interface Options  
T-60 Se rie s COM port:  
1 or 2  
-MOD  
-GE9  
-TI3  
1
Spe c ific PLC Mode l:  
315, 325, 330, 425, 435  
-TI5  
1
TI505  
T-60 Se rie s COM port:  
1 or 2  
Da ta Highwa y Plus TM  
(DF1)  
-PL5  
TM  
T-60 Se rie s COM port:  
1 or 2  
DH-485  
-SL5  
-OM  
-PL2  
(DF1)  
T-60 Se rie s COM port:  
1 or 2  
Host Link  
T-60 Se rie s COM port:  
1 or 2  
PLC-2 Progra m m ing Port  
-ID1  
Se e IDEC Se c tion  
Se e Mitsubishi Se c tion  
Se e Squa re D Se c tion  
Se e IDEC Se c tion  
Se e Mitsubishi Se c tion  
Se e Squa re D Se c tion  
-MFX  
-SQD  
61  
T-60 Operator's Manual  
cmd specifies the type of PLC protocol that you are initiating. This can vary  
depending upon PLC manufacturer, and possibly model, according to the  
following table:  
Examples:  
10 CALL PLCINIT(1,1)  
Establishes communication with a Modbus, GE Series 90, PLC-5, SLC-500,  
Omron Hostlink, or TI505 PLC (depending on the installed interface option)  
with an ID (address) of 1.  
10 CALL PLCINIT(1,435)  
Establishes communication with a TI435 PLC with an ID (address) of 1  
(when the -TI3 option is installed).  
10 CALL PLCINIT(1,2)  
Establishes communication with a Modicon, AB PLC-5, or SLC-500 with an  
ID (address) of 1 on COM 2.  
62  
PLC Interface Commands CALL PLCREAD Statement  
CALL PLCREAD Statement  
Purpose:  
This command is used to read the value(s) in a PLC’s registers, the status of  
bits, or any other accessible memory location within the PLC. Refer to the  
-PL5 and -SL5 for information on how to use this command with the  
Allen-Bradley PLC-5 and SLC-500 processors.  
Syntax:  
CALL PLCREAD(id,cmd,start address,# ofregisters/bits,variable/array)  
Comments:  
id specifies the address of the PLC from which you wish to read data. This  
number is usually 1 when interfacing to one PLC.  
cmd specifies the read operation you wish to perform. See the table below for  
the read operation possibilities.  
start address is the starting address of the bit(s) or register(s) you are  
interested in reading. In the case of the PLC interfaces implemented so far,  
this does not include a data type specifier (%, $, !, etc.)  
Table 5  
Read Operation Options  
MOD  
GE9  
TI3  
TI5  
OM1  
PL2  
Cm d  
Func tion  
Re a d PLC CPU Sta tus  
Re a d Disc re te Input Sta tus  
Re a d Disc re te Output Sta tus  
Re a d Re giste r  
Typic a l Da ta /Re sponse *  
2 words; ID, run sta tus  
1 word pe r 16 bits  
1 word pe r 16 bits  
1 word pe r re giste r  
1 word pe r re giste r  
1 word with 8 bits  
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
1
2
·
·
·
3
4
5
Re a d Input Re giste r  
6
Quic k Sta tus  
·
·
·
·
7
Re a d Ana log Inputs  
Re a d Ana log Outputs  
Re a d Disc re te Inte rna ls/Coils/Re la ys  
Re a d Holding Re la ys  
Re a d Auxila ry Re la ys  
1 word pe r re giste r  
1 word pe r re giste r  
1 word pe r 16 bits  
1 word pe r 16 bits  
1 word pe r 16 bits  
8
·
·
·
·
9
10  
11  
*The Da ta /Re sponse form a t de sc ribe d he re is typic a l. Re fe r to the se c tion re ga rding your spe c ific inte rfa c e for  
63  
T-60 Operator's Manual  
# of registers/bits is the number of consecutive registers, memory locations,  
or bits that you wish to read. Most PLC interfaces only allow you to read one  
at a time, and for many applications that is all you will need to read. If this is  
the case, # of registers/bits will be 1. If you wish to read more than one  
register or memory location at a time, this number will be the number of  
consecutive registers or locations you wish to read. If you are reading the  
status of more than one I/O bit, this number will be the number of  
consecutive bits you wish to read.  
variable/array is the variable name or array name where you wish to store  
the data you are reading. This variable MUST be a short integer (%  
variable). If the value of # of registers/bits (see above) is 1, this will be a  
variable expression. If you are reading registers or memory locations that  
are stored as words (  
= 1, 4, 5, 6, 7, 8) and the  
is  
# of registers/bits  
cmd  
greater than one, this will be a short integer array (make sure you properly  
dimension the array prior to using it). If you are reading the status of more  
than one, but less than 16 I/O bits, you will be reading one word, and  
therefore will need to use a single short integer. If you are reading more than  
16 bits, you will need to use a short integer array. The dimension of the array  
variable will be the next integer greater than the desired number of bits  
divided by 16. For example, if you wish to read the status of bits 1-24 you will  
need to dimension your array to at least two since 24/16 = 1.5 and two is the  
next greater integer. Remember, any time you are reading more than one  
word of data (more than one register or more than 16 bits) you must use a  
dimensioned short integer array.  
Examples:  
10 DIM stat%(2)  
20 CALL PLCREAD(1,1,0,2,stat%(1))  
This command returns the ID of the PLC as stat%(1) and the current run  
status as stat%(2) from the Modbus or GE Series 90 PLC with an id (address)  
= 1.  
10 DIM regdat%(10)  
20 CALL PLCREAD(1,4,16,5,regdat%(4))  
This command returns the contents of register 16 in regdat%(4), register 17  
in regdat%(5), register 18 in regdat%(6), register 19 in regdat%(7), register 20  
in regdat%(8), from any of the PLC’s currently implemented.  
10 CALL PLCREAD(1,5,47,1,regdat1%)  
This command reads the data in input register number 47 in the Modbus  
PLC with id (address) = 1 and stores it in the variable regdat1%  
10 CALL PLCREAD(1,7,3,1,analog1%)  
This command reads the value of analog input number 3 in a GE Series 90 or  
TI 505 PLC with address = 1 and stores it in the variable analog1%  
64  
PLC Interface Commands CALL PLCWRITE Statement  
CALL PLCWRITE Statement  
Purpose:  
This command is used to write value(s) to a PLC’s register(s), memory  
location(s), or to force one or more output bits in a PLC. Refer to the -PL5  
and -SL5 for information on how to use this command with the  
Allen-Bradley PLC-5 and SLC-500 processors.  
Syntax:  
CALL PLCWRITE(id,cmd,start address,# of  
registers/bits,expression/variable/array )  
Comments:  
specifies the address of the PLC to which you wish to write. This number  
id  
is usually 1 when interfacing to one PLC.  
cmd specifies the write operation you wish to perform. See the table below  
for the write operation possibilities:  
start address is the starting address of the bit(s) or register(s) you are  
interested in writing. In the case of the Modbus, this does not include a data  
type specifier (%, $, !, etc.)  
Table 6  
Write Operation Options  
MOD  
GE9  
TI3  
TI5  
OM1  
PL2  
Cm d  
Func tion  
Cle a r Sta tus  
Write Input Bit(s)  
Write Output Bit(s)  
Write to a Re giste r  
N/A  
Typic a l Da ta *  
Any 5 words  
16 bit words  
16 bit words  
1 word pe r re giste r  
N/A  
1
2
3
4
5
6
7
8
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
N/A  
N/A  
N/A  
N/A  
·
·
·
·
·
·
Write to Ana log Output(s)  
1 word pe r output  
Write to Disc re te  
·
·
9
16 bit words  
Inte rna ls/Coils/Re la ys  
·
·
10  
11  
Write to Holding Re la ys (bits)  
Write to Auxila ry Re la ys (bits)  
16 bit words  
16 bit words  
65  
T-60 Operator's Manual  
# of registers/bits is the number of consecutive registers, memory locations,  
or bits that you wish to set. Many PLC Interfaces only allow you to set one at  
a time, and for many applications that is all you will need to read. If this is  
the case, # of registers/bits will be 1.If you wish to set more than one register  
or memory location at a time, this number will be the number of consecutive  
registers or locations you wish to set. If you are writing the status of more  
than one I/O bit, this number will be the number of consecutive bits you wish  
to set.  
expression/variable/arrayis the expression, variable or array data you  
wish to write to the PLC’s I/O, registers, or other memory locations. If the  
value of # of registers/bits (see above) is 1, this will be an expression or a  
variable. If the number of words is greater than one, this must be an array  
(make sure you properly dimension the array prior to using it).If you wish to  
write the status of up to 16 I/O bits, you will be writing one word, and  
therefore will need to use an expression or discrete variable name. If you  
wish to set more than 16 consecutive bits, you will need to use an array. The  
dimension of the array variable will be the next integer greater than the  
desired number of bits divided by 16. For example, if you wish to set the  
status of bits 1-24 you will need to dimension your array to at least two since  
24/16 = 1.5 and two is the next greater integer. Remember, any time you are  
writing more than one word of data (more than one register or more than 16  
bits) you must use a dimensioned array variable.  
Examples:  
10 DIM stat(10)  
20 CALL PLCWRITE(1,1,1,5,stat(1))  
This command clears the status in a TI305/405 PLC  
10 CALL PLCWRITE(1,3,12,5,13)  
This command writes a 1 to outputs 12, 14, and 15, and a 0 to outputs 13 and  
16 in a PLC with an id (address) = 1. Note that 13 represents the binary  
“01101" which is the bit pattern desired.  
10 DIM newdat%(10)  
20 CALL PLCWRITE(1,4,5,2,newdat%(4))  
This command writes the value of newdat%(4) to register 5 and newdat%(5)  
to register 6 in a PLC with an id (address) = 1.  
10 DIM anout%(10)  
20 CALL PLCWRITE(1,8,1,2,anout%(1))  
This command writes the value of analog1% to analog output 1 and to analog  
output 2 in a GE Series 90 or TI505 PLC with address = 1  
PLC Specific Information  
In general, PLC’s from various manufacturers behave similarly. There are,  
however, some “quirks” that need to be mentioned. Also, various PLC’s deal  
with Operator Interfaces in various ways. Some allow access to the registers,  
memory locations, and discrete I/O through the CPU’s programming port,  
while others require some sort of communication module to be added to allow  
the CPU and Operator Interface to interact properly. This section deals with  
the criteria specific to each of the T-60 Series PLC Interface Options —  
command variances, communication hardware, cabling, etc.  
66  
PLC Interface Commands PLC Specific Information  
Table 7  
Option  
PLC’s Supported  
Protocol  
Communicate via  
Com Parameters  
Any Modicon PLC  
Supporting Modbus:  
Micro 84, 484, 584,  
184/384, 884, 984/381,  
etc.  
-MOD  
Modbus  
Programming Port  
Auto-Detect  
19.2 kbaud, 1 stop bit,  
8 data bits, odd parity  
-GE9  
-TI3  
GE Fanuc Series 90-30  
SNP  
Programming Port  
GE Fanuc Series 90-70  
TI Model 315  
SNP  
Programming Port  
Same as 90-30  
Auto-Detect  
Auto-Detect  
Auto-Detect  
Auto-Detect  
CCM  
CCM  
CCM  
CCM  
DCU  
DCU  
DCU  
DCM  
TI Model 325  
TI Model 330  
TI Model 425  
CPU Serial Interface  
Port  
TI Model 435  
CCM  
Auto-Detect  
Auto-Detect  
Auto-Detect  
Auto-Detect  
Auto-Detect  
Auto-Detect  
Auto-Detect  
Auto-Detect  
Auto-Detect  
CPU Serial Interface  
Port  
-TI5  
TI Model 520(C)  
TI Model 530(C)  
TI Model 525  
TI Direct Connect  
TI Direct Connect  
TI Direct Connect  
TI Direct Connect  
TI Direct Connect  
TI Direct Connect  
TI Direct Connect  
TI Direct Connect  
1785-KE  
CPU Serial Interface  
1Port  
CPU Serial Interface  
Port  
CPU Serial Interface  
Port  
TI Model 535  
CPU Serial Interface  
Port  
TI Model 560  
CPU Serial Interface  
Port  
TI Model 565  
CPU Serial Interface  
Port  
TI Model 545  
CPU Serial Interface  
Port  
TI Model 575  
Computer  
(Asynchronous) Port  
Set Full Duplex & BCC,  
All others auto-detected  
-PL5  
-SL5  
Allen Bradley PLC-5  
Allen Bradley PLC-5  
Allen Bradley PLC-500  
Computer  
(Asynchronous) Port  
Set Full Duplex & BCC,  
All others auto-detected  
1770-KF2  
Computer  
(Asynchronous) Port  
Set Full Duplex & BCC,  
All others auto-detected  
1747-KE  
-OM1  
-PL2  
Omron Host Link  
Alle n Bra dle y PLC-2  
Alle n Bra dle y PLC-2  
Host Link  
1771-KA2  
RS232C Port  
Auto-Detect  
Auto-Detect  
Programming Port  
Programming Port  
Programming Port  
Auto-Detect  
67  
T-60 Operator's Manual  
MOD Interface Option  
Communications:  
The -MOD Option communicates via the Modbus protocol. It was developed  
to allow the T-60 Series to communicate easily to the Modicon PLC’s that use  
the Modbus protocols (Micro 84, 484, 584, 184/384, 884, 984/381, etc.) It also  
works well with communication modules available for other PLC’s like GE  
Fanuc’s Serial Communications Module (Cat.# IC693CMM311 used in RTU  
Mode). When used with a Modicon PLC, the communications occurs via the  
programming port. The T-60 Series does auto-detect for the serial  
communications parameters, therefore no special procedures are necessary  
for configuring the serial port on the PLC. The CALL PLCINIT command  
takes care of configuring COM1 on the T-60 Series device and initializing the  
communications with the PLC.  
Connections:  
The -MOD Option comes with the proper cable to interface to the Modicon  
PLC. For those who need to change the length of the cable, the proper  
Figure 22  
T-60 Series to Modbus  
Communication Connections  
connections are shown below:  
Command Variations:  
There are no variations between the descriptions of CALL PLCINIT, CALL  
PLCREAD, and CALL PLCWRITE in the previous section and the Modbus  
implementation of those commands.  
68  
PLC Interface Commands PLC Specific Information  
GE9 Interface Option  
Communications:  
The -GE9 Option uses GE Fanuc’s SNP Protocol to communicate to their  
Series 90 PLCs. Access to the PLC occurs via the programming port. In the  
near future, they will also be offering a Serial Communications Module that  
supports SNP which will allow simultaneous connections to the PLC by more  
than one T-60 or T-61, as well as a programmer. Check with GE for  
availability. If you need to allow simultaneous communication to one Series  
90 from both a T-60 Series unit and a programming device, GE’s Serial  
Communication Module (catalog # IC693CMM311) supports the Modbus  
protocol when in RTU mode. You would then need to use the -MOD option to  
communicate to the PLC. See the previous section for more information. The  
rest of this section will deal with the -GE9 SNP protocol currently only  
available through the programming port. (Note: since the original  
publication of this document, it appears that GE Fanuc has released a  
version of of Serial Communications Module that does support the SNP  
protocol.)  
Table 8  
T60 Series / RS232  
Communication Protocol  
-GE9 Interface Option  
Pa ra m e te r—  
Se tting—  
Mode  
RS422  
Ba ud Ra te  
Da ta Bits  
8
Stop Bit(s)  
1
Pa rity  
Odd  
19.2 kba ud  
When first sending the CALL PLCINIT command, the T-60 Series unit  
configures COM1 to have the following parameters:  
Make sure that the configuration of the programming port of the PLC  
matches these parameters, or the CALL PLCINIT command will fail and you  
will get an error message like “PLC link not established.”  
Connections:  
The -GE9 Option comes with the proper cable to interface to a GE Fanuc  
Series 90 PLC. For those who need to change the length of the cable, the  
proper connections are shown below:  
Command Variations:  
There are no variations between the descriptions of CALL PLCINIT, CALL  
PLCREAD, and CALL PLCWRITE in the previous section and the GE Series  
90 SNP implementation of those commands.  
69  
T-60 Operator's Manual  
TI3 Interface Option  
Communications:  
The -TI3 Option uses Texas Instruments’ CCM protocol for communicating to  
TI Series 305 and Series 405 PLC’s. The Series 305 PLC’s (Models 315, 325,  
and 330) communicate via a DCU module. The communication parameters  
are auto-detected by the T-60 Series device. Therefore, you don’t need to set  
up any communication parameters in your PLC. The TI Model 425  
communicates via the DCM module. It’s communication parameters are also  
auto-detected. The TI Model 435 has a serial communication port built into  
the CPU module. No other communications module is necessary. As with  
the other Models, the T-60 Series auto-detects the 435’s communication  
parameters. In all cases, the communication protocol is RS232C, so use the  
RS232C port, not the RS422 port, if you have a choice.  
Connections:  
The -TI3 Option comes with the proper cable to interface to a TI 305 or 405  
Series PLC. For those who need to change the length of the cable, the proper  
connections are shown below:  
Figure 23  
10T-60 Series to GE Series 90  
Communication Connections  
70  
PLC Interface Commands PLC Specific Information  
Command Variations:  
TI Series 305 and 405 PLC’s return 5 words of network status information  
when using CALL PLCREAD with cmd = 1. The following example describes  
a typical way to read the status information:  
bold  
10 DIM stat%(5)  
20 CALL PLCREAD(1,1,0,5,stat%(1))  
Numbers in  
changed  
cannot be  
This will store Last Error and Previous Error in stat%(1), Number of  
Successful Communications in stat%(2), Number of Erroneous  
Communications in stat%(3), Number of Retries For Header in stat%(4), and  
Number of Retries for Data in stat%(5). (See your PLC manual for more  
details) You must read 5 words of data any time you wish to read the  
network status.  
You can reset the status registers by using the CALL PLCWRITE command  
with cmd = 1. You must write five words. The data can be arbitrary, since  
the net result is resetting the status registers, no matter what you write. See  
the example:  
Numbers in bold cannot be  
10 DIM newstat%(5)  
20 CALL PLCWRITE(1,1,0,5,newstat%(1))  
changed  
(See your PLC manual for more details) You must write 5 words of data  
any time you wish to reset the network status.  
All other commands behave as described in previous sections.  
71  
T-60 Operator's Manual  
TI5 Interface Option  
Communications:  
The -TI5 Option uses Texas Instruments’ Direct Connect protocol for  
communicating to TI Series 505 PLC’s. All models in the TI500/505 Series  
have an RS232C serial port on the CPU module. The T-60 Series -TI5 Option  
uses this port for communication to the PLC. Both the T-60 and T-61 auto  
detect the communication parameters, so no setup is needed to get the two  
devices communicating. The only caution is to make sure that no passwords  
exist that would not allow the T-60 Series unit access to the programming  
port.  
Connections:  
The -TI5 Option comes with the proper cable to interface to a TI 505 Series  
PLC. For those who need to change the length of the cable, the proper  
connections are shown below:  
Figure 24  
T-60 Series to TI Series 305 or TI  
Series 405 RS232C  
Communication Connections  
Command Variations:  
The following table will help make the terminology of the previous sections  
make more sense with respect to the TI Series 505 documentation. It is a  
cross reference between the Memory Type in the PLC documentation and the  
cmd for the CALL PLCREAD and CALL PLCWRITE commands.  
72  
PLC Interface Commands PLC Specific Information  
Table 9  
Cross Reference  
-TI5 Memory Type Vs. Call  
PLCREAD / PLCWRITE  
READ  
WRITE  
Cm d  
Me m ory Type  
STW Me m ory  
X Me m ory  
Y Me m ory  
V Me m ory  
N/A  
Ra nge  
1-15  
Da ta / Re sponse  
1 word pe r re giste r  
1 word pe r 16 bits  
1 word pe r 16 bits  
1 word pe r re giste r  
N/A  
·
·
·
·
1
2
3
4
5
6
7
8
9
1-1024  
1-1024  
1-NNNN  
N/A  
·
·
N/A  
N/A  
N/A  
·
·
·
WX Me m ory  
WY Me m ory  
CR Me m ory  
1-1024  
1-1024  
1-32768  
1 word pe r re giste r  
1 word pe r re giste r  
1 word pe r 16 bits  
·
·
73  
T-60 Operator's Manual  
PL5 Interface Option  
Communications:  
The -PL5 Interface Option allows the T-60 Series to communicate to the  
Allen Bradley PLC-5 (Data Highway Plus™) through the 1785-KE or  
1770-KF2 Series B Data Highway™ RS-232-C Interface Modules. The  
communications cable is EMERSON EMC’s standard Null Modem cable  
(N-MODEM-25-25 for the T-61 and N-MODEM-9-25 for the T-60 ).  
Connections:  
The -PL5 Option comes with the proper cable to interface direct to a  
PLC-520,540 or 580 DF1 port. You may also choose a cable to interface to  
either a 1785-KE or a 1770-KF2 Series B Data Highway™ RS-232-C  
Interface Module. The cable sections are as follows:  
Using the -PL5 with a 1785 KE Module:  
T-60 - 20-00138-01  
T-61 - 20-00141-01  
Using the -PL5 with a 1770 KF2 Module:  
T-60 - 20-00109-02  
T-61 - 20-00109-01  
Using the -PL5 with a PLC-520, 540, or 580 DF1 port:  
T-60 - 20-00109-02  
T-61 - 20-00141-01  
Refer to the end of this section for the schematics for the above cables.  
Allen-Bradley 1785 KE and 1770 KF2 Set-Up:  
Correctly setting the dip switches on the 1785 KE or 1770 KF2 Interface  
Module is an important step in the set up process. Furthermore it is a good  
idea to make sure that your 1785 KE or 1770 KF2 is working properly by  
communicating to the PLC5 via the KE or KF2 interface and Allen Bradley’s  
programming software (APS). Follow the appropriate Allen-Bradley user’s  
manual for setting up your system to communicate in this fashion. Once you  
have successfully communicated with between the PC and your PLC,  
communicating with the Eason is a snap.  
Table 10  
1785 KE Interface Module Dip  
Switch Settings  
SWITCH NUMBER  
1
2
3
4
5
6
7
8
SW1  
SW2  
SW3  
SW4  
Up  
Dn  
Dn  
Up  
Up  
Dn  
Dn  
Up  
Up  
Up  
Up  
Up  
Up  
Dn  
Up  
Up  
Dn  
Up  
Up  
Dn  
Up  
Up  
74  
PLC Interface Commands PLC Specific Information  
Configure the 1785 KE dip switches in the following manner:  
Configure the 1770 KF2 dip switches in the following manner:  
Table 11  
1770 KF2 Interface Module Dip  
Switch Settings  
SWITCH NUMBER  
1
2
3
4
5
6
SW1  
SW2  
SW3  
SW4  
SW5  
SW6  
SW7  
SW8  
Dn  
Dn  
Up  
Up  
Up  
Dn  
Up  
Dn  
Dn  
Dn  
Up  
Up  
Up  
Up  
Dn  
Up  
Up  
Dn  
Dn  
Up  
Up  
Up  
Up  
75  
T-60 Operator's Manual  
Command Variations:  
The CALL PLCREAD and CALL PLCWRITE commands for the PLC-5 are  
significantly different from the other PLC’s described here. The following  
descriptions apply to the -PL5 Option only:  
CALL PLCREAD Statement  
Syntax:  
CALL PLCREAD  
)
(id, file, address, [bit], count, variable/array  
Comments:  
This command is specific to the -PL5 Interface Option.  
id specifies the address of the PLC from which you wish to read data.  
This number is usually 1 when interfacing to one PLC.  
file specifies the file number that you wish to access.  
address is the address of the first element to access in the above file.  
[bit] is an optional parameter which specifies the starting bit location of the  
bits you wish to read. If you are reading words (as in reading a  
register value), leave this field blank (ie, ...address,,count,...). If you  
are reading bits (I/O points, internal coils, etc.) specify the starting bit in the  
element you are addressing (address). This could be any bit from 0-15.  
count specifies the number of bits and/or elements that you wish to read. If  
you are reading data in the form of words, it is the number of consectutive  
elements you wish to read. If you are reading bits, it is the number of  
consecutive bits you wish to read.  
variable/array is the variable name or single dimension array name where  
you wish to store the data you are reading. If the value of count (see above) is  
1, this will be a variable expression. If you are reading elements that are  
stored as words and count is greater than one, this will be an array (make  
sure you properly dimension the array prior to using it). If you are reading  
the status of more than one, but less than 16 bits, you will be reading one  
word, and therefore can use a discrete variable name. If you are reading  
more than 16 bits, you will need to use an array. The dimension of the array  
variable will be the next integer greater than the desired number of bits  
divided by 16. For example, if you wish to read the status of bits 1-24 you  
will need to dimension your array to at least two since 24/16 = 1.5 and two is  
the next greater integer. Remember, any time you are reading more than one  
word of data (more than one register or more than 16 bits) you must use a  
dimensioned array variable.  
76  
PLC Interface Commands PLC Specific Information  
Examples:  
10 DIM regdat%(10)  
20 CALL PLCREAD(1,4,16,,5,regdat%(4))  
This command returns the contents of element 16 in regdat%(4), element 17  
in regdat%(5), element 18 in regdat%(6), element 19 in regdat%(7), element  
20 in regdat%(8), from file #4 in the PLC-5 with id #1.  
10 CALL PLCREAD(2,5,47,,1,regdat1%)  
This command reads the data in input element number 47 in file #5 in the  
PLC-5 with id (address) = 2 and stores it in the variable regdat1%  
10 DIM stat%(2)  
20 CALL PLCREAD(1,1,1,15,18,stat%(1))  
This command would access file 1 in the PLC with an id of 1. It would return  
the status of address 1, bit 15, and address 2, bits 0-14 in stat%(1) and the  
status of address 2, bit 15 and address 3 bit 0 (and 14 zeros) in stat%(2).  
CALL PLCWRITE Statement  
Syntax:  
CALL PLCWRITE(id, file, address, [bit], count, variable/array )  
Comments:  
This command is specific to the -PL5 Interface Option.  
id specifies the address of the PLC in which you wish to write data. This  
number is usually 1 when interfacing to one PLC.  
file specifies the file number that you wish to write to.  
address is the address of the first element to write to in the above file.  
[bit] is an optional parameter which specifies the starting bit location of the  
bits you wish to write. If you are writing words (as in writing a  
register value), leave this field blank (i.e., ...address,,count,...). If you  
are writing bits (I/O points, internal coils, etc.) specify the starting bit in the  
element you are addressing (address). This could be any bit from 0-15.  
count specifies the number of bits and/or elements that you wish to set. If  
you are writing data in the form of words, it is the number of consecutive  
elements you wish to write. If you are setting bits, it is the number of  
consecutive bits you wish to set.  
variable/array is the variable name or single dimension array name where  
you wish to store the data you are writing. If the value of  
(see above) is  
count  
1, this could be a variable expression. If you are writing elements that are  
stored as words and count is greater than one, this will be an array (make  
77  
T-60 Operator's Manual  
sure you properly dimension the array prior to using it). If you are setting  
more than one, but less than 16 bits, you will be writing one word, and  
therefore can use a discrete variable name. If you are setting more than 16  
bits, you will need to use an array. The dimension of the array variable will  
be the next integer greater than the desired number of bits divided by 16.  
For example, if you wish to set bits 1-24 you will need to dimension your  
array to at least two since 24/16 = 1.5 and two is the next greater integer.  
Remember, any time you are writing more than one word of data (more than  
one register or more than 16 bits) you must use a dimensioned array  
variable.  
Examples:  
10 DIM regdat%(10)  
20 CALL PLCWRITE(1,4,16,,5,regdat%(4))  
This command writes the contents of regdat%(4) in element 16, regdat%(5) in  
element 17, regdat%(6) in element 18, regdat%(7) in element 19, and  
regdat%(8) in element 20 to file #4 in the PLC-5 with id (address) of 1.  
10 CALL PLCWRITE(2,5,47,,1,regdat1%)  
This command writes the data in regdat1% into element number 47 in file #5  
in the PLC-5 with id (address) of 2.  
10 DIM stat%(2)  
20 CALL PLCWRITE(1,2,33,12,5,13)  
This command sets bits 12, 14, and 15 to a 1, and bits 13 and 16 to a 0 in  
element 33 in file #2 in PLC with an id (address) of 1.  
78  
PLC Interface Commands PLC Specific Information  
-SL5 Interface Option  
Communications:  
The -SL5 Interface Option allows the T-60 Series to communicate to the Allen  
Bradley SLC-500 (DH-485Ô) through the 1747-KE DH-485Ô to RS-232-C  
Interface Module. The communications cable is EMERSON EMC’s standard  
Null Modem cable (N-MODEM-25-9 for the T-61 and N-MODEM-9-9 for the  
T-60 ).  
Connections:  
The -SL5 Option comes with the proper cable to interface to a 1747-KE  
Interface Module. For those who need to change the length of the cable, the  
proper connections are shown below:  
Figure 25  
T-60 Series to Allen Bradley  
1747-KE Module  
Communication Connections  
SLC-500 Setup:  
The SLC-500 needs to have a 1747-KE interface module installed in it. If the  
processor is a stand-alone type (SLC500), you may have to add a two slot  
option rack to add this interface module. Some newer SLC-500’s have a  
built-in serial port, this port can be used to gain direct access to SLC-500 by  
using the DF1 protocol. This document refers only to the setup and use of the  
1747-KE module. Please consult EMERSON EMC for other applications.  
79  
T-60 Operator's Manual  
Follow the setup guidelines for the 1747-KE module exactly. If possible, use  
your Allen-Bradley programming software to communicate to the SLC-500  
once you perform all of the setup operations. In general you can use the  
default settings as long as you change the DF1 Port Setup Parameters, select  
the correct node address, and select FULL DUPLEX operation. If you want  
to check all of the parameters using a terminal connected to the setup port,  
use the following parameters:  
DF1 Port Setup Parameters:  
19.2K baud (this is not critical, the -SL5 option will auto-baud and find  
yourbaud rate)  
8 data bits  
No parity  
1 stop bit.  
DH-485 Port Setup Parameters:  
Node Address - 2 Set the PLC to node address 1 (this is performed  
with the Allen-Bradley setup software for the PLC). The -SL5  
interface will reside at node address 0.  
Max Node Address - 31  
Message Time-out - 1000ms  
Pass Through - Enabled  
Baud Rate - 19200  
DF1 Protocol Menu:  
Full Duplex  
DF1 Protocol Full Duplex Setup Menu:  
Duplicate Packet Detection - Disabled  
Checksum - BCC  
Constant Carrier Detect - Disabled  
Modem Init String - (blank)  
Embedded Response Detect - Embedded Response  
ACK Time-out - 1.0 Seconds  
ENQuriy Retries - 2  
NAK Received Retries - 2  
Be sure to return the 1747-KE module to the Run mode (jumper settings),  
and jumper the 1747-KE for RS-232. Connect the DF1 port to COM1 on the  
T-60 Series product, and you should be able to communicate. Try sending a  
CALL PLCINIT(1,1) to see if you get a Ready response. If you do, start  
programming! If not, try checking that you are using COM1 on the T-60  
Series product. Make sure you are plugged into the DF1 port, not the  
configuration port on the 1747-KE. Make sure you are no longer in setup  
mode for the 1747-KE, and that the jumpers are set to RS-232.  
Command Variations:  
The CALL PLCREAD and CALL PLCWRITE commands for the SLC-500 are  
significantly different from the other PLC’s described here. The following  
descriptions apply to the -SL5 Option only:  
80  
PLC Interface Commands PLC Specific Information  
CALL PLCREAD Statement  
Syntax:  
CALL PLCREAD(id, type, file, address, [bit], count, variable/array )  
Comments:  
This command is specific to the -SL5 Interface Option.  
id specifies the address of the PLC from which you wish to read data. This  
number is usually 1 when interfacing to one PLC. See the SLC-500 Setup  
section for more information on the selection of the id.  
type specifies the file type that is required for a specific file. The allowable  
file types and their use are as follows:  
0
1
2
3
4
5
6
7
Outputs - The -SL5 option will not allow direct access to I/O.  
Inputs - The -SL5 option will not allow direct access to I/O.  
Status - S file types  
Bit - B file types  
Timer - T file types  
Counter - C file types  
Control - R file types  
Integer - N file types  
file specifies the file number that you wish to access. The use of a specific  
file is restricted to files which your program access. For instance, if your  
program uses no timers, and you access a timer file you will get a “PLC LINK  
NOT ESTABLISHED” error.  
address is the address of the first element to access in the specified file.  
Allen-Bradley restricts reading from or writing to locations which are not  
specified within a program. For example if your program only access N7:0  
through N7:4 and you try to read from N7:5 (one address higher than your  
program access), you will get an error. To avoid this problem, we suggest  
that your program access data at least one word higher than words that the  
-SL5 interface is trying to access. When addressing bit files (type 3), you  
must specify the WORD address, rather than the BIT address. For example  
to access B3:250 you need to think of accessing word address B3:15/10. See  
the examples at the end of this section for further clarification.  
bit is the starting bit location of the bits you wish to read. If you are  
reading words (as in reading a register value), leave this field blank  
(i.e., ...address,,count,...). If you are reading bits in any file type, specify  
the starting bit in the element you are addressing (address). This could be  
any bit from 0-15.  
count specifies the number of bits and/or elements that you wish to read. If  
you are reading data in the form of words, it is the number of consecutive  
elements you wish to read. If you are reading bits, it is the number of  
consecutive bits you wish to read.  
variable/array is the variable name or single dimension array name where  
81  
T-60 Operator's Manual  
you wish to store the data you are reading. If the value of count (see above) is  
1, this will be a variable expression. If you are reading elements that are  
stored as words and count is greater than one, this will be an array (make  
sure you properly dimension the array prior to using it). If you are reading  
the status of more than one, but less than 16 bits, you will be reading on  
word, and therefore can use a discrete variable name. If you are reading  
more than 16 bits, you will need to use an array. The dimension of the array  
variable will be the next integer greater than the desired number of bits  
divided by 16. For example, if you wish to read the status of bits 1-24 you  
will need to dimension your array to at least two since 24/16 = 1.5 and two is  
the next greater integer. Remember, any time you are reading more than one  
word of data (more than one register or more than 16 bits) you must use a  
dimensioned array variable.  
Examples:  
10 DIM regdat%(5)  
20 CALL PLCINIT(1,1)  
30 CALL PLCREAD(1,7,7,16,,5,regdat%(1))  
Line 10 dimensions the array regdat%(10) for future use, line 20 initializes  
the PLC (this only needs to be done once in your program). Line 30 returns  
the contents of N7:16 in regdat%(1), N7:17 in regdat%(2), N7:18 in  
regdat%(3), N7:19 in regdat%(4), and N7:20 in regdat%(5) in the SLC-500  
with a node address of 1.  
10 CALL PLCREAD(2,5,5,3,,1,reg%)  
This command reads the data in C5:3 in an SLC-500 with node address of 2  
and stores it in the variable reg%  
20 CALL PLCREAD(1,3,3,1,8,15,stat%)  
This command would access B3:1 in the PLC with a node address of 1. It  
would return the status of B3:1/8 through B3:2/7 stat%. Note that if your  
PLC’s program does not access any elements from B3:2/8 through B3:255/15,  
an error will result. This is because the SLC-500 protects (disables external  
access) to elements which are above the highest accessed elements in a file.  
Normally this is not a problem for most file types, and status types. B type  
files however, are protected in bytes. The -SL5 interface reads and writes in  
words. Therefore, if the -SL5 interface accesses any low bits within the PLC  
(bits 0 through 7), make sure that your PLC program accesses any bits in the  
next higher byte. The easiest way to insure that you will not have a problem  
is to make sure your PLC program accesses the next higher word in memory.  
82  
PLC Interface Commands PLC Specific Information  
CALL PLCWRITE Statement  
Syntax:  
CALL PLCWRITE(  
)
id,type, file, address, [bit], count, variable/array  
Comments:  
This command is specific to the -SL5 Interface Option.  
specifies the address of the PLC in which you wish to write data. This  
id  
number is usually 1 when interfacing to one PLC. See the SLC-500 Setup  
section for more information on the selection of the id.  
type specifies the file type that is required for a specific file. The allowable  
file types and their use are as follows:  
0
1
2
3
4
5
6
7
Outputs - The -SL5 option will not allow direct access to I/O.  
Inputs - The -SL5 option will not allow direct access to I/O.  
Status - S file types  
Bit - B file types  
Timer - T file types  
Counter - C file types  
Control - R file types  
Integer - N file types  
file specifies the file number that you wish to write to. The use of a specific  
file is restricted to files which your program access. For instance, if your  
program uses no timers, and you access a timer file you will get a “PLC LINK  
NOT ESTABLISHED” error.  
address is the address of the first element to write to in the above file..  
Allen-Bradley restricts reading from or writing to locations which are not  
specified within a program. For example if your program only access N7:0  
through N7:4 and you try to read from N7:5 (one address higher than your  
program access), you will get an error. To avoid this problem, we suggest  
that your program access data at least one word higher than words that the  
-SL5 interface is trying to access. When addressing bit files (type 3), you  
must specify the WORD address, rather than the BIT address. For example  
to access B3:250 you need to think of accessing word address B3:15/10. See  
the examples at the end of this section for further clarification.  
bit is the starting bit location of the bits you wish to write. If you are  
writing words (as in writing a register value), leave this field blank  
(i.e., ...address,,count,...). If you are writing bits (I/O points, internal coils,  
etc.) specify the starting bit in the element you are addressing (address).  
This could be any bit from 0-15.  
count specifies the number of bits and/or elements that you wish to set. If  
you are writing data in the form of words, it is the number of consecutive  
elements you wish to write. If you are setting bits, it is the number of  
consecutive bits you wish to set.  
variable/array is the variable name or single dimension array name where  
83  
T-60 Operator's Manual  
you wish to store the data you are writing. If the value of count (see above) is  
1, this could be a variable expression. If you are writing elements that are  
stored as words and count is greater than one, this will be an array (make  
sure you properly dimension the array prior to using it). If you are setting  
more than one, but less than 16 bits, you will be writing one word, and  
therefore can use a discrete variable name. If you are setting more than 16  
bits, you will need to use an array. The dimension of the array variable will  
be the next integer greater than the desired number of bits divided by 16.  
For example, if you wish to set bits 1-24 you will need to dimension your  
array to at least two since 24/16 = 1.5 and two is the next greater integer.  
Remember, any time you are writing more than one word of data (more than  
one register or more than 16 bits) you must use a dimensioned array  
variable.  
Examples:  
10 DIM regdat%(5)  
20 CALL PLCINIT(1,1)  
30 CALL PLCWRITE(1,7,7,16,,5,regdat%(1))  
Line 10 dimensions the array regdat%(10) for future use, line 20 initializes  
the PLC (this only needs to be done once in your program). Line 30 writes  
the contents of regdat%(1) in N7:16, regdat%(2) in N7:17, regdat%(3) in  
N7:18, regdat%(4) in N7:19, and regdat%(5) in N7:20 in the SLC-500 with a  
node address of 1.  
10 CALL PLCWRITE(2,5,5,3,,1,reg%)  
This command writes the data contained in the variable reg% into C5:3 in an  
SLC-500 with a node address of 2.  
20 CALL PLCWRITE(1,3,3,1,8,15,stat%)  
This command would write the contents of variable stat% into the PLC data  
bits B3:1/8 through B3:2/7. Note that if your PLC’s program does not access  
any elements from B3:2/8 through B3:255/15, an error will result. This is  
because the SLC-500 protects (disables external access) to elements which  
are above the highest accessed elements in a file. Normally this is not a  
problem for most file types, and status types. B type files however, are  
protected in bytes. The -SL5 interface reads and writes in words. Therefore,  
if the -SL5 interface accesses any low bits within the PLC (bits 0 through 7),  
make sure that your PLC program accesses any bits in the next higher byte.  
The easiest way to insure that you will not have a problem is to make sure  
your PLC program accesses the next higher word in memory.  
20 CALL PLCWRITE(1,7,7,15,1,1,0)  
This command writes a zero to bit location N7:15/1. Note the restrictions  
mentioned in the example above.  
84  
PLC Interface Commands PLC Specific Information  
-OM1 Interface Option  
Communications:  
The -OM1 Option uses the Omron Host Link protocol for communicating to  
all suitably equipped Omron PLC’s. The Omron Host Link port is connected  
to the T-60 or T-61’s COM1 port via the supplied cable. Both the T-60 and  
T-61 auto detect the communication parameters, so no setup is needed to get  
the two devices communicating.  
Connections:  
The -OM1 Option comes with the proper cable to interface to a Host Link  
equipped PLC. For those who need to change the length of the cable, the  
proper connections are shown below:  
Figure 26  
T-60 Series to Omron Host Link  
RS232C Communication  
Connections  
Command Variations:  
The following table will help the terminology of the previous sections make  
more sense with respect to the Omron Host Link documentation. It is a cross  
reference between the Memory Type in the PLC documentation and the cmd  
for the CALL PLCREAD and CALL PLCWRITE commands.  
85  
T-60 Operator's Manual  
Table 12  
Cross Reference  
-OM1 Memory Type Vs. Call  
PLCREAD / PLCWRITE  
READ  
WRITE  
Cm d  
Me m ory Type  
Sta tus Word  
IR & SR  
IR & SR  
DM  
Ra nge  
Da ta / Re sponse  
1 word  
·
·
·
1
2
*
*
*
*
*
*
*
*
*
*
*
1 word pe r 16 bits  
1 word pe r 16 bits  
1 word pe r re giste r  
N/A  
·
·
3
·
4
5
N/A  
6
N/A  
N/A  
7
N/A  
N/A  
8
N/A  
N/A  
·
·
·
·
9
LR  
1 word pe r 16 bits  
1 word pe r 16 bits  
1 word pe r 16 bits  
·
10  
11  
HR  
AR  
·
PLC De pe nde nt  
Addressing bits in the -OM1 Option is a little different than in the rest of the  
PLC interfaces. The -OM1 Option utilizes the Host Link bit  
addressing scheme which combines the WORD address and the BIT address  
into one number. For the IR, SR, LR, HR, and AR areas data is accessed in  
this fashion. To read a bit at word 5 bit 3, will require an address of 503,  
word 11 bit 13 requires the address of 1113. For example, to access the IR  
data area, word 5, bits 6 through 9, use the following command  
The -OM1 Option limits you to  
reading or writing a maximum  
of 32 words of data (512 bits)  
during one read or write  
operation. For example, you  
are restricted to accessing 32  
registers in the DM area with  
one CALL PLCREAD or CALL  
PLCWRITE command.  
CALL PLCREAD(0, 2, 506, 4, A)  
This command accesses word 5, bit 6 and reads four bits placing the result  
in variable A. Note that the four bits will be aligned in variable A with bit  
506 in the 2^0 location 507 in the 2^1 location and so on. This makes bit  
testing within a BASIC program very simple.  
Writes to individual bit locations in the Omron PLC is performed via a read  
modify write process. EXTREME care should be taken when using data bits  
which may be updated during a scan. Host Link only allows data to be read  
and written to on WORD boundaries. This forces the -OM1 Option to read  
surrounding bits to obtain an entire word, then sets or clears the desired bits  
and write the recomposed words back to the PLC. If the data the -OM1  
Option reads surrounding the operation is updated during a scan,  
unpredictable results may occur. Writing to outputs may be something to  
avoid if your program does not continually update them. Reads do not suffer  
from this problem.  
86  
PLC Interface Commands PLC Specific Information  
The Omron status write must be performed in the following manner:  
CALL PLCWRITE(0,1,0,1,mode)  
mode: 0 - program  
1 - debug  
2 - monitor  
3 - run  
The Omron PLC must be in the monitor mode to enable write commands to  
perform without errors. A CALL PLCINIT( id, 1) places the PLC into the  
monitor mode, but if your application has a programming panel or some other  
peripheral device attached, it may be possible for the operator to disable  
writes to the PLC. Use the status write function to return the PLC to the  
monitor mode when necessary.  
87  
T-60 Operator's Manual  
-PL2 Interface Option (Preliminary)  
Communications:  
The -PL2 Option uses the programming port protocol for communicating to  
the Allen Bradley PLC-2. The T-60 Series can use the programming port on  
the PLC-2 CPU or the programming port on the 1771-KA2 Interface Module.  
The PLC-2 communication parameters are not configurable, so issuing the  
CALL PLCINIT command will configure COM1 on the T-60 Series device to  
the proper settings for the PLC-2.  
The Data that cannot be accessed in the EMERSON EMC implementation of  
the PLC-2 protocol as noted in the PLC-2 programming manual (Page C-3 -  
Data Table Organization) are: Processor Work Areas No. 1 and No. 2, the  
Reserved Area, the Expanded Data Table and/or User Program Area, and the  
User Program Area. All other areas are accessible via the CALL PLCREAD  
and CALL PLCWRITE commands.  
Connections:  
The -PL2 Option comes with the proper cable to interface to a PLC-2 directly  
through the programming port, or to the programming port of the 1771-KA2.  
For those who need to change the length of the cable, the proper connections  
are shown below:  
Figure 27  
T-60 Series to Allen Bradley  
PLC-2 Communication  
Connections  
Command Variations:  
There are no variations between the descriptions of CALL PLCINIT, CALL  
PLCREAD, and CALL PLCWRITE in the previous section and the Allen  
Bradley PLC-2 or 1771-KA2 implementation of those commands.  
88  
PLC Interface Commands PLC Specific Information  
-IDEC FA-1J\FA2-J Interface Option  
Communications:  
The -IDEC option uses the Idec protocol to communicate between the Series  
T-60 unit and the PLC. The unit is configured by using the  
command.  
-plcinit(x,y)  
Table 13  
T60 Series / RS232  
Communication Protocol  
-IDEC FA-1J\FA2-J Interface  
Option  
Pa ra m e te r—  
FA-1J—  
Mode  
Ba ud Ra te  
C9600 ba ud  
C9600 ba ud  
Da ta Bits  
Stop Bit(s)  
Pa rity  
None  
Eve n  
RS232  
RS232  
8
8
1
1
FA-2J—  
Connections:  
In order for the SeriesT-60 and the Idec unit to communicate, a specialized  
cable is sent with the Eason unit. The pinout for this cable is shown in the  
table below illustrating the view for both the T-60 and the T-61.  
Figure 28  
T-60 Series to IDEC FA-1J and  
FA-2J PLC Communication  
Connections  
89  
T-60 Operator's Manual  
Available Commands:  
The commands listed in the table below list the commands available for the  
Idec FA-1J and the Idec FA-2J interfaces.  
Table 14  
T-60 Series commands and  
addrss ranges for the Idec FA-1J  
and the FA-2J  
Cm d#  
Com m a nd  
Sta tus  
Addre ss  
none  
Size  
BIT  
Re a d  
Write  
FA-IJ  
FA-2J  
1
2
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
·
In_Out (Input)  
0-157  
BIT  
2
In_Out (Expa nsion Input)  
In_Out (Output)  
In_Out (Expa nsionOutput)  
Re giste r  
2000-2157  
200-357  
2200-2357  
800-899  
1500-1799  
400-717  
2400-2717  
0-79  
BIT  
3
BIT  
·
·
·
·
·
·
·
3
BIT  
4
WORD  
WORD  
BIT  
4
Re giste r (Expa nsion Re giste r)  
Inte rna l Re la y  
9
·
9
Inte rna l Re la y (Expa nsion Re la y)  
Tim e r Va lue  
BIT  
12  
13  
14  
15  
16  
17  
WORD  
WORD  
WORD  
WORD  
BIT  
·
·
·
·
·
·
Tim e r Va lue  
0-79  
·
Counte r Va lue  
0-47  
Counte r Pre se t  
0-47  
·
·
Shift Re giste r  
0-127  
Te n Mil Tim e r  
T-61-1179  
WORD  
CALL PLCINIT Statement  
Purpose:  
This command is used to initialize communication with the IDEC FA-1J  
and FA-2J series PLC. CALL PLCINIT must be issued prior to any other  
communication (reading or writing) to the IDEC PLC. CALL PLCINIT  
setsup specific communications parameters. If the CALL PLCINIT  
command fails, the T-60 Series unit will break your program and generate  
the error message “PLC link not established.” If this occurs, make sure that  
the connections and communications configurations are correct.  
90  
PLC Interface Commands PLC Specific Information  
Syntax:  
CALL PLCINIT(id,cmd)  
Comments:  
id specifies the address of the PLC that you wish to initialize. For the  
FA-1J and FA-2J series PLC, this number will always be 1.  
cmd specifies the type of PLC protocol that you are initiating :  
1 - FA-1J on com port 1  
2 - FA-2J on com port 1  
3 - FA-1J on com port 2  
4 - FA-2J on com port 2  
Examples:  
10 CALL PLCINIT(1,1)  
Establishes communication with the Idec FA-1J on communications port 1.  
10 CALL PLCINIT(1,4)  
Establishes communication with the Idec FA-2J on communications port 4.  
CALL PLCREAD Statement  
Purpose:  
This command is used to read the value(s) in a PLC’s registers, the status  
of bits, or any other accessible memory location within the PLC.  
Syntax:  
(id,cmd,start address,# ofregisters/bits,variable/array)  
CALL PLCREAD  
Comments:  
id specifies the address of the IDEC - always use 1.  
cmd specifies the read operation you wish to perform. See the table under  
Available Commands for the read operation possibilities:  
address describes where in memory the value is to be read from  
-
count - number of bits to be read ( when using command of size WORD this  
will be a 1 )  
variable/number - this is the variable or number that is to be written in  
memory in the case of a the variable that will store the value being read  
Examples  
CALL PLCREAD( 1, 9, 400, 13, a%)  
Starting at address 400 in the internal relays of the Idec, this command will  
instruct the PLC to read the first 13 bits and store the result into a%.  
91  
T-60 Operator's Manual  
CALL PLCREAD( 1, 12, 30, 1, t% )  
This will capture the monitor value of a timer.  
CALL PLCWRITE Statement  
Purpose:  
This command is used to write value(s) to the IDEC’s register(s), memory  
location(s), or to force one or more output bits in a PLC.  
Syntax:  
CALL PLCWRITE(id,cmd,start address,# of  
registers/bits,expression/variable/array)  
Comments:  
id specifies the address of the IDEC - always use 1.  
cmd specifies the write operation you wish to perform. See the table below  
for the write operation possibilities:  
address describes where in memory the value is to be stored or read from  
-
count - number of bits to be read ( when using command of size WORD this  
will be a 1 )  
variable/number - this is the variable or number that is to be written in  
memory in the case of a write or the variable that will store the value being  
read  
Examples:  
CALL PLCWRITE( 1, 4, 805, 1, 12345)  
This command tells the Idec PLC to write in register #805 the value 12345.  
This function is only available in the FA-2J PLC.  
CALL PLCWRITE( 1, 9, 400, 13, 4077)  
This instructs the PLC to write into the internal relays at address 400, the  
value of 4077 using 13 bits.  
92  
PLC Interface Commands PLC Specific Information  
-Mitsubishi FX PLC Interface ( -MFX )  
Communications:  
The -MFX Option uses the Mitsubishi FX’s RS422 port to communicate with  
the T-60 Series products. For the T-60 this utilizes com port 1 and either  
port is available for use in the T-61.  
Connections:  
In order for the SeriesT-60 and the FX unit to communicate, a specialized  
cable is sent with the Eason unit. The pinout for this cable is shown in the  
table below for the T-60 and the T-61.  
Figure 29  
T-60 Series to the Mitsubishi FX  
series PLC Communication  
Connections  
93  
T-60 Operator's Manual  
Available Commands:  
The commands listed in the table below list the commands available for the  
Mitsubishi FX series interfaces.  
Table 15  
Mitsubishi FX Series Interface  
Commands  
Cm d #  
Com m a nd  
PLC Da ta Type  
Addre ss  
Size  
1
2
3
Inputs  
X
Y
0-177  
0-177  
BIT  
BIT  
Outputs  
0-511  
4
Re giste rs  
D
Word  
8000-8255  
5
6
7
8
0-1023  
9
Auxilia ry Re la ys  
Tim e r Conta c ts  
M
T
BIT  
BIT  
8000-8255  
10  
11  
0-255  
0-255  
0-255  
Counte r  
C
T
BIT  
Conta c ts  
12  
13  
14  
15  
Tim e r Va lue  
WORD  
Counte r Va lue  
C
0-199  
WORD  
CALL PLCINIT Statement  
Purpose:  
This command is used to initialize communication with the FX. CALL  
PLCINIT must be issued prior to any other communication (reading or  
writing) to the specified PLC. CALL PLCINIT initializes the BAUD rate to  
9600 Baud, 7 data bits, even parity. Either COM 1, COM 2, RS422, and  
RS232 can be specified. Note that on T-60 ’s COM1, RS422 is  
recommended. If the CALL PLCINIT command fails, the T-60 Series unit  
will break your program and generate the error message “PLC link not  
established.” If this make sure that the connections and communications  
configurations are correct. If they are OK, check to make sure that the FX is  
powered up and ready to accept Commands.  
94  
PLC Interface Commands PLC Specific Information  
Syntax:  
CALL PLCINIT(id,cmd)  
Comments:  
id specifies the address of the FX - always use 1.  
cmd specifies the communications mode:  
1 - RS422, COM1 - most common and recommended.  
2 - RS422, COM2 - T-61 only  
3 - RS232 COM 1 - Must use an RS232 to RS422 adapter  
4 - RS232 COM 2 - Must use an RS232 to RS422 adapter  
Examples:  
10 CALL PLCINIT(1,1)  
Establish communications with the PLC via the T-60 Series COM 1 RS422  
Port.  
CALL PLCREAD Statement  
Purpose:  
This command is used to read the value(s) in a PLC’s registers, the status of  
bits, or any other accessible memory location within the PLC.  
Syntax:  
CALL PLCREAD(id,cmd,start address,# of  
registers/bits,variable/array )  
Comments:  
id specifies the address of the FX - always use 1.  
cmd specifies the read operation you wish to perform. See the table below  
for the read operation possibilities:  
start address is the starting address of the bit(s) or register(s) you are  
interested in reading. Inputs and Outputs (data types X and Y) are specified  
in OCTAL just like you would specify in the PLC ladder logic program. The  
type specified for this parameter if a variable is to be used is an integer: %.  
# of registers/bits is the number of consecutive registers, memory locations,  
or bits that you wish to read. If you wish to read one bit or register, set this  
parameter to 1. If you wish to read more than one register or memory  
location at a time, this number will be the number of consecutive registers or  
locations you wish to read. If you are reading the status of more than one I/O  
bit, this number will be the number of consecutive bits you wish to read.  
variable/array is the variable name or array name where you wish to store  
the data you are reading. If you are reading only one register or bit, you may  
use any variable type you wish. If you are reading multiple registers or more  
95  
T-60 Operator's Manual  
than 16 bits of data, this variable MUST be a short integer (%) array  
variable. If you are reading registers or memory locations that are stored as  
words and the # of registers/bits is greater than one, this will be a short  
integer array (make sure you properly dimension the array prior to using it).  
If you are reading the status of more than one, but less than 16 I/O bits, you  
will be reading one word, and therefore will need to use a single short  
integer. If you are reading more than 16 bits, you will need to use a short  
integer array. The dimension of the array variable will be the next integer  
greater than the desired number of bits divided by 16. For example, if you  
wish to read the status of bits 1-24 you will need to dimension your array to  
at least two since 24/16 = 1.5 and two is the next greater integer. Remember,  
any time you are reading more than one word of data (more than one register  
or more than 16 bits) you must use a dimensioned short integer array.  
Examples:  
10 DIM regdat%(10)  
20 CALL PLCREAD(1,4,16,5,regdat%(4))  
This command returns the contents of register 16 in regdat%(4), register 17  
in regdat%(5), register 18 in regdat%(6), register 19 in regdat%(7), register 20  
in regdat%(8), from any of the PLC’s currently implemented.  
10 CALL PLCREAD(1,5,47,1,regdat1%)  
This command reads the data in input register number 47 with id (address)  
=1 and stores it in the variable regdat1%  
CALL PLCWRITE Statement  
Purpose:  
This command is used to write value(s) to the FX’s register(s), memory  
location(s), or to force one or more output bits in a PLC.  
Syntax:  
CALL PLCWRITE(  
id,cmd,start address,# of  
registers/bits,expression/variable/array )  
Comments:  
id specifies the address of the FX - always use 1.  
cmd specifies the write operation you wish to perform. See the table below  
for the write operation possibilities:  
start address is the starting address of the bit(s) or register(s) you are  
interested in writing. Inputs and Outputs (data types X and Y) are specified  
in OCTAL just like you would specify in the PLC ladder logic program. The  
type specified for this parameter if a variable is to be used is an integer: %.  
# of registers/bits is the number of consecutive registers, memory locations,  
or bits that you wish to write. If you wish to write one bit or register, set this  
parameter to 1. If you wish to write more than one register or memory  
96  
PLC Interface Commands PLC Specific Information  
location at a time, this number will be the number of consecutive registers or  
locations you wish to write. If you are writing the status of more than one  
I/O bit, this number will be the number of consecutive bits you wish to write.  
expression/variable/array is the expression, variable or array data you  
wish to write to the PLC’s I/O, registers, or other memory locations. If the  
value of # of registers/bits (see above) is 1, this will be an expression or a  
variable. If the number of words is greater than one, this must be an array  
(make sure you properly dimension the array prior to using it). If you wish to  
write the status of up to 16 I/O bits, you will be writing one word, and  
therefore will need to use an expression or discrete variable name. If you  
wish to set more than 16 consecutive bits, you will need to use an array. The  
dimension of the array variable will be the next integer greater than the  
desired number of bits divided by 16. For example, if you wish to set the  
status of bits 1-24 you will need to dimension your array to at least two since  
24/16 = 1.5 and two is the next greater integer. Remember, any time you are  
writing more than one word of data (more than one register or more than  
16bits) you must use a dimensioned array variable.  
Examples:  
10 CALL PLCWRITE(1,3,9,2,3)  
This command writes a 1 to outputs 0 and 1. Note that 3 represents the  
binary “11" which is the bit pattern desired.  
10 DIM newdat%(10)  
20 CALL PLCWRITE(1,4,5,2,newdat%(4))  
This command writes the value of newdat%(4) to register 5 and newdat%(5)  
to register 6 in a PLC with an id (address) = 1.  
Table 16  
PLC/Model/Signal Name  
PLC  
7
T-60  
3
Signa l Na m e  
GND  
16  
3
4
TXD-  
5
TXD+  
15  
2
6
RXD-  
7
RXD+  
SHIELD  
DSR+  
N/C  
4
8
8
GND  
20  
21  
17  
GND  
PWE  
DSR-  
97  
T-60 Operator's Manual  
-SQD SQUARE D SY/MAX PLC Interface  
Communications:  
The SQD PLC option uses the SY/MAX RS422 port to communicate with the  
T-60 Series products. The connections are as follows:  
Figure 30  
T-60 Interface Cable:  
Figure 31  
T-61 Interface Cable:  
98  
PLC Interface Commands PLC Specific Information  
CALL PLCINIT Statement  
Purpose:  
This command is used to initialize communication with the SY/MAX. CALL  
PLCINIT must be issued prior to any other communication (reading or  
writing) to the specified PLC. CALL PLCINIT auto detects the baud rate and  
parity. Either COM 1 or COM 2 can be specified. Note that on T-60 ’s  
only COM 1 is available (T-60 ’s only have one RS422 port). A single  
non-networked route is specified by the id, see comments below. If the  
CALL PLCINIT command fails, the T-60 Series unit will break your program  
and generate the error message “PLC link not established.” If this happens,  
make sure that the connections and communications configurations are  
correct. If they are OK, check to make sure that the SY/MAX is powered up  
and ready to accept commands.  
Syntax:  
CALL PLCINIT(id,cmd)  
Comments:  
id specifies the route for the SY/MAX. Specifying an id of 0 will specify an  
route of 0,100, an id of 1 will specify a route of 1,101. Networking route  
specifications will be available in future versions of this interface, check with  
EMERSON EMC for more details.  
cmd specifies the communications mode:  
1 - RS422, COM 1  
2 - RS422, COM 2 - T-61 only  
Examples:  
10 CALL PLCINIT(0,1)  
Establish communications with the PLC via the T-60 Series COM 1 RS422  
Port, specifying a route of 0,100.  
CALL PLCREAD Statement  
Purpose:  
This command is used to read the value(s) in the SY/MAX PLC’s registers. It  
can read words or bits in all allowable addresses for a specific SY/MAX PLC.  
Syntax:  
CALL PLCREAD(  
id,start address,[bit position],# of  
registers/bits,variable/array )  
99  
T-60 Operator's Manual  
Comments:  
id specifies the route. See CALL PLCINIT above.  
start address is the starting address of the register(s) you are interested in  
reading.  
[bit position] is an optional parameter which specifies the position within a  
16 bit register to start reading from. An allowable range for bit position is 1  
through 16. By specifying this parameter, a bit (single or multiple) read will  
be performed. For example specifying a  
of 2 will allow the read to  
bit position  
place the data at the PLC’s bit 2 (2^1) in the bit 0 (2^0 bit) position of the  
variable/array (Note that all Eason documentation references bits 0 through  
15 for bits inside variables in the EASON, while SY/MAX documentation  
references bits 1 through 16 for registers in the PLC... sorry about the  
confusion).. Note that only the contents of 1 register’s bits may be read at a  
time. This means that a bit position of 9 (2^8 bit) will only allow 8 bits to be  
read. This is due to the fact that there are only 16 bits available in one  
register, and we are starting at bit 8 this leaves a result of 8 bits.  
Omitting the bit position parameter will specify that the read will return  
whole registers rather than bits. Refer to the following examples for samples  
of how to specify bits or whole registers.  
# of registers/bits is the number of consecutive registers, memory locations,  
or bits that you wish to read. If the bit position parameter is omitted, # of  
registers/bits will specify the number of 16 bit registers to read. If you wish  
to read more than one register or memory location at a time, this number will  
be the number of consecutive registers or locations you wish to read. If you  
have included a bit position parameter, this number will be the number of  
consecutive bits you wish to read.  
variable/array is the variable name or array name where you wish to store  
the data you are reading. If you are reading only one register or bit, you may  
use any variable type you wish. If you are reading multiple registers, this  
variable MUST be a short integer (%) array variable. If you are reading  
registers or memory locations that are stored as words and the  
# of  
registers/bits is greater than one, this will be a short integer array (make  
sure you properly dimension the array prior to using it). If you are reading  
the status of more than one, but less than 16 I/O bits, you will be reading one  
word, and therefore will need to use a single short integer. Remember, any  
time you are reading more than one register you must use a dimensioned  
short integer array.  
Examples:  
10 DIM regdat%(10)  
20 CALL PLCREAD(1,16,,5,regdat%(4))  
This command returns the contents of register 16 in regdat%(4), register 17  
in regdat%(5), register 18 in regdat%(6), register 19 in regdat%(7), and  
register 20 in regdat%(8).  
10 CALL PLCREAD(1,47,,1,regdat1%)  
100  
PLC Interface Commands PLC Specific Information  
This command reads the data in register number 47 with and stores it in the  
variable regdat1%.  
10 CALL PLCREAD(1,100,5,2,bits%)  
This command reads two bits from register 100 starting at bit position 5. The  
result is placed in the variable bits% with register 100, bit 5 in bit position 0,  
and register 100 bit 6 in bit position 6.  
CALL PLCWRITE Statement  
Purpose:  
This command is used to write 16 bit words and bits into the SY/MAX PLC’s  
‘register(s).  
Syntax:  
CALL PLCWRITE(id,start address,[bit position], # of  
registers/bits,expression/variable/array)  
Comments:  
id specifies the route. See CALL PLCINIT above.  
start address is the starting address of the register(s) you are interested in  
writing.  
[bit position] is an optional parameter which specifies the position within a  
16 bit register to start writing to. An allowable range for bit position is 1  
through 16. By specifying this parameter, a bit (single or multiple) write will  
be performed. For example specifying a  
of 2 will allow the write  
bit position  
to place data contained in the variable/array bit 0 (2^0 bit) in the bit 2 (2^1  
bit) position of the result (Note that all Eason documentation references bits  
0 through 15 for bits inside variables in the EASON, while SY/MAX  
documentation references bits 1 through 16 for registers in the PLC... sorry  
about the confusion). Note that only the contents of 1 register’s bits may be  
written at a time. This means that a bit position of 9 (2^8 bit) will only allow  
8 bits to be written. This is due to the fact that there are only 16 bits  
available in one register, and we are starting at bit 8 this leaves a result of 8  
bits.  
Omitting the bit position parameter will specify that the write will return  
whole registers rather than bits. Refer to the following examples for samples  
of how to specify bits or whole registers  
# of registers/bits is the number of consecutive registers, memory locations,  
or bits that you wish to write. If the bit position parameter is omitted, # of  
will specify the number of 16 bit registers to write. If you wish  
registers/bits  
to write more than one register or memory location at a time, this number  
will be the number of consecutive registers or locations you wish to write (up  
to a maximum of 16). If you have included a bit position parameter, this  
number will be the number of consecutive bits you wish to write.  
101  
T-60 Operator's Manual  
variable/array is the variable name or array name where you wish to store  
the data you are writing. If you are writing only one register or bit, you may  
use any variable type you wish. If you are writing multiple registers, this  
variable can either be a short integer (%) array variable or a constant (like  
1234). If you are writing registers or memory locations that are stored as  
words and the  
is greater than one, this will be a short  
# of registers/bits  
integer array (make sure you properly dimension the array prior to using it).  
If you are writing the status of more than one, but less than 16 I/O bits, you  
will be writing one word, and therefore will need to use a single short integer.  
Remember, any time you are writing more than one register you must use a  
dimensioned short integer array.  
Examples:  
10 CALL PLCWRITE(1,15,1,2,3)  
This command writes a 1 to register 15 bits 1 and 2. Note that 3 represents  
the binary “11" which is the bit pattern desired.  
10 DIM newdat%(10)  
20 CALL PLCWRITE(1,5,,2,newdat%(4))  
This command writes the value of newdat%(4) to register 5 and newdat%(5)  
to register 6 in a PLC with an id (address) = 1.  
10 CALL PLCWRITE(1,100,,1,1234)  
Note that you cannot write to multiple locations with the same data (i.e.  
CALL PLCWRITE(1,100,,10,1234) - this will generate a “VARIABLE  
REQUIRED” BASIC error). This operation must be performed by initializing  
elements of a dimensioned array and writing the array in the following  
fashion:  
10 DIM A%(16)  
20 FOR N=1 TO 16: A%(N)=1234: NEXT  
30 CALL PLCWRITE(1,100,,10,  
This command writes 1234 to register 100.  
102  
Appendix A - List of Figures  
Appendix - A  
List of Figures  
Introduction  
Figure 1  
Block Diagram......................................................................... 3  
Installation  
Figure 2  
Figure 3  
Figure 4  
Figure 5  
Figure 6  
Figure 7  
Figure 8  
Figure 9  
Figure 10  
Figure 11  
Figure 12  
Figure 13  
Panel Cut-Out ......................................................................... 6  
Mounting ................................................................................. 7  
Mounting Clips........................................................................ 7  
Install Top Mounting Screws ................................................. 8  
Mounting Holes....................................................................... 8  
Drill Holes ............................................................................... 9  
Install T-60 .............................................................................. 9  
T-60 Bottom Panel .................................................................. 9  
RS232 Minimum Connections.............................................. 11  
RS422 Connections ............................................................... 11  
RS485 Connector................................................................... 11  
One Channel of the 8 Bit I/O................................................ 13  
ApplicationBuilder  
Figure 14  
Serial Connections ................................................................ 15  
Builder Mode Screen............................................................. 16  
Figure 15  
Screen Editor  
Figure 16  
Help Screen ........................................................................... 30  
Application Examples  
Figure 17  
Installation ............................................................................ 35  
Installation - T-60 W/More Than One DX Drive................. 36  
Figure 18  
Event Driven Software  
Figure 19  
Event System - One Schedule Element ............................... 52  
Connector Pin-Out Specifications  
Figure 20  
Physical Dimensions............................................................. 56  
PLC Interface Commands  
Figure 21  
Figure 22  
T-60 Series to Modbus Comm Connections ......................... 67  
T-60 Series to GE Series 90 Comm Connections................. 70  
A-1  
T-60 Operator's Manual  
Figure 23  
Figure 24  
Figure 25  
Figure 26  
Figure 27  
Figure 28  
T-60 Series to TI Series 305 or TI Series 405 RS232C  
Communication Connections................................................ 71  
T-60 Series to TI Series 505 RS232C Communication  
Connections ........................................................................... 73  
T-60 Series to Allen Bradley 1747-KE Module  
Communication Connections................................................ 81  
T-60 Series to Omron Host Link RS232C Communication  
Connections ........................................................................... 87  
100T-60 Series to Allen Bradley PLC-2 Communication  
Connections ........................................................................... 91  
T-60 Series to IDEC FA-1J and FA-2J PLC Communication  
Connections ........................................................................... 93  
Figure 29  
T-60 Series to the Mitsubishi FX series PLC  
Communication Connections............................................... 97  
Figure 30  
Figure 31  
T-60 Interface Cable:.......................................................... 103  
T-61 Interface Cable:.......................................................... 103  
A-2  
Appendix A - List of Figures  
A-3  
Appendix B - List of Tables  
Appendix - B  
List of Tables  
Installation  
Table 1  
COM1 and COM2 Connectors Pin-Outs .............................. 10  
I/O Connector Pin-Out .......................................................... 12  
Table 2  
PLC Interface Commands  
Table 3  
Table 4  
Table 5  
Table 6  
Table 7  
Table 8  
Current PLC Interface Options............................................ 58  
PLC Protocol Interface Options............................................ 60  
Read Operation Options ....................................................... 61  
Write Operation Options ..................................................... 63  
PLC Summary....................................................................... 65  
T60 Series / RS232 Communication Protocol  
-GE9 Interface Option........................................................... 69  
Table 9  
Cross Reference  
-TI5 Memory Type Vs. Call PLCREAD / PLCWRITE ....... 74  
Table 10  
Table 11  
Table 12  
1785 KE Interface Module Dip Switch Settings.................. 76  
1770 KF2 Interface Module Dip Switch Settings................ 76  
Cross Reference  
-OM1 Memory Type Vs. Call PLCREAD / PLCWRITE ..... 88  
Table 13  
Table 14  
T60 Series / RS232 Communication Protocol  
-IDEC FA-1J\FA2-J Interface Option................................. 93  
T-60 Series commands and addrss ranges for the Idec FA-1J  
and the FA-2J........................................................................ 94  
Table 15  
Table 16  
Mitsubishi FX Series Interface Commands......................... 98  
PLC/Model/Signal Name .................................................... 102  
B-1  

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